DE2624998A1 - PRINT DEVICE FOR TRANSLUCENT PICTURES - Google Patents

Description

Xerox Corporation, Rochester, N.Y. / USA Printing device for translucent images

The invention relates to an electrophotographic printing machine for reproducing colored, translucent images. In particular The invention relates to an electrophotographic printing device for the production of colored, opaque, permanent copies based on colored translucent images.

In the electrophotographic printing process, a conductive member is charged and with a light image of an original document exposed. The light image irradiates the charged part of the photoconductive surface. This selectively discharges the charge, an electrostatic latent image corresponding to the original document is recorded thereon. A development system brings a developer mixture of carrier particles and toner particles into contact with the electrostatic latent image. The toner particles are electrostatically attracted from the carrier particles to the latent image and form an image thereon from toner powder. The image of toner powder is transferred from the photoconductive surface to a sheet of carrier material. After the image from toner powder has been transferred to the carrier material, a fuser fixes the image of toner powder thereon in a permanent manner Shape.

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The above description explains the basic concept of electrophotographic printing. There were different devices designed for specific purposes where this concept is applied. For example, devices are currently on the market widely used to make enlarged copies of a microfilm. Devices of this type are described in US patents 3,424,525 (Towers et al, 1969), 3,542,468 (Blow, Jr., 1970) and 3,547,533 (Stokes et al, 1970).

With the advent of colored electrophotographic printing a strong need arose for the production of enlarged, opaque color images starting from translucent ones Color images. The multicolor electrophotographic printing is essentially the same as that described above Procedure. In multi-color printing, the light image is filtered to create an electrostatic latent image on the photoconductive element that corresponds to a single color of the original document. This electrostatic latent image of the individual Color is developed with toner particles of a color that is complementary to the color of the filtered light image. After that, that will Transferring an image from toner powder to a sheet of carrier material. This process is used for successive different colored Repeated photographs. Each generated toner powder image is transferred to the sheet of carrier material, overlying and aligned with the previous toner powder image. This creates a multi-layered toner powder image on the sheet of carrier material generated. The multi-layered toner powder image is fixed on the sheet of carrier material in a permanent form, while it is through a Fuser is running, producing a persistent color copy of the original document.

The reproduction of colored translucent images has also been achieved by projecting a monochromatic light image of the translucent colored image through a screen and a

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Fresnel lens through, which are arranged on the plate of the device. The filtered, modulated light image discharges the charged ones Selectively portions of the photoconductive surface. Successive monochromatic light images are generated, and the result The resulting opaque copy corresponds to the one projected through colored translucent image. The above process is described in detail in co-pending application no. 540 617 of January 13, 1975.

The object of the invention is to improve the quality of the copies, generated from colored, translucent images with an electrophotographic printing machine.

This object is achieved by an electrophotographic printing machine for reproducing a colored, translucent image, which is characterized according to the invention by a photoconductive element, a device for charging the photoconductive Element to a substantially uniform level, a filter device, a screen element closely adjacent to the photoconductive element is arranged, and means for projecting a light image of the translucent color image through the filter device and the screen element to form a modulated monochrome light image for the selective Discharge of the charged portion of the photoconductive element to record a monochromatic electrostatic latent image thereon.

The electrophotographic printing machine includes a photoconductive one Element and means for charging the photoconductive element to a substantially uniform level. The printing device comprises a filter device for generating monochromatic light images. A screen element is closely adjacent to the photoconductive one Element arranged. Means are provided for a light image of the colored, translucent image through the To project filter device and the screen element therethrough. In this way, the charged part of the photoconductive element

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selectively discharge roents through the modulated monochrome light image, to record a monochromatic electrostatic latent image thereon.

Further features and usefulnesses of the invention emerge from the description of exemplary embodiments on the basis of the figures. From the figures show:

Fig. 1 is a schematic perspective view of an electrophotographic Printing device according to the invention; and

FIG. 2 is a schematic representation of the optical system used in the printing device of FIG.

The invention is described in the following on the basis of a preferred exemplary embodiment described, but it should be emphasized that this does not limit the invention to this embodiment will.

For a general understanding of the described elektrophotographir see color printing device according to the invention is always to the Drawings referenced. In the drawings, the same reference numerals denote the same elements. The color electrophotographic printing machine according to the invention is particularly well suited to making enlarged, opaque color copies starting from translucent To produce color images, however, it follows from the context that it is also well suited for the production of Black-and-white copies based on black-and-white photographs.

As can be seen from Figure 1, the electrophotographic Printing machine uses a photoconductive element with a drum 10 rotatable within the machine frame (not shown) is mounted. The photoconductive surface 12 is attached to and wrapped around the drum 10. Preferably the photoconductive surface 12 made of a panchromatic selenium alloy

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as described in U.S. Patent 3,655,377 (Sechak, 1972).

The drum 10 rotates at a predetermined speed in the direction of arrow 14 and moves through a series of processing stations through, which are arranged around the circumference. A timing dial is in the area of one end the shaft of the drum 10 is mounted. The clock control disk works together with the logic device of the device for synchronization the actuation in the various processing stations with the rotation of the drum 10. Each of the processing stations is briefly explained below.

Initially, the drum 10 rotates through the charging station A, a corona generating device, generally designated by the numeral 16 and spray ions onto the photoconductive surface 12 and a relatively high, substantially uniform Charge generated on it. A suitable corona generating device is described in U.S. Patent 3,875,407 (Hayne, 1975), which relevant parts are hereby included in the disclosure of the present application.

After the photoconductive surface 12 is charged to a substantially uniform potential, the drum 10 rotates it charged part to exposure station B. In exposure station B, a color-filtered light image of a colored, translucent one Image 18, in this embodiment a 35 mm slide, on the charged part of the photoconductive surface 12 projected. The colored, translucent image 18 is converted into a Slide projector 20 entered. The slide projector 20 includes a light source 22 which is used to illuminate the translucent image 18 is suitable. In addition, the slide projector 20 includes a lens 24 with an adjustable focal point for generating a magnified Image of the translucent color image 18. A suitable one Slide projector is sold under the trade name "Carousel, Modell

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750-H "manufactured by Eastman Kodak Corporation of Rochester, New York. An enlarged image of the translucent color image 18 is directed onto a mirror 26. The mirror 26 reflects the enlarged image downward through a Fresnel lens 28. Between the Fresnel lens 28 and a transparent plate 30 is an optionally provided, opaque one Sheet 32 with an opening inserted therein, i.e. a picture frame or explanatory structural framework that can be adopted as a compositional framework. The composition frame 32 defines one opaque edge extending from that formed on plate 30 translucent color image extends from outward. Information can be written on the frame 32. Thus, on the translucent plate 30 produces a combined image, i.e., an image comprising the opaque sheet and the translucent Contains color image. This enables the scanning system to generate a flowing light image therefrom. The scanning system includes a moving lens system indicated generally at 34 and one indicated generally at 36 Color filter mechanism. Lamps 38 move in time with the lens system 34 and the filter mechanism 36 to produce successive, and to illuminate. In this way, a combined flowing light image of the enlarged translucent image is generated, which passes through fresnel lens 28 and composition frame 32.

If you wish, you can use the translucent image instead of an enlarged one a copy of the same size can be made. In this operating mode, the projector 20 only serves as an additional source of illumination. The translucent image 18 is placed on the plate 30 with the composition frame 32 still over part of it the plate 30 lies. The opening in frame 32 is designed to extend from the edges of translucent image 18 extends outwards. Furthermore, a plurality of translucent

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sigen images are placed on the plate 30, the composition frame 32 has a plurality of openings therein adapted to be superimposed over any translucent image will. In this mode of operation, the copy produced by the electrophotographic printing machine comprises a plurality of true to size translucent images.

The combined light image of the translucent image and the composition frame are taken from the mirror 40 through the lens 34 and the filter 36 reflects through and forms a monochromatic light image. The monochromatic light image is reflected by a mirror 42 reflected through a screen element 44 and produces a modulated monochromatic light image. An auxiliary light source (not shown) can provide additional lighting through the screen 44. The modulated monochrome light image is irradiated the charged portion of the photoconductive surface 12 and records a single color electrostatic latent image thereon. The filter mechanism 36 places selected color filters in the optical path of the lens 34 during the exposure process. The appropriate one Filter acts on the rays of light which pass through lens 34, creating an electrostatic latent image the photoconductive surface 12 corresponding to a single color contained in the original document is. The exposure system will be explained in detail later with reference to FIG.

After the electrostatic latent image has been recorded on the photoconductive surface 12, the drum 10 rotates to Development station C. In development station C there are three individual Arranged developer units, generally designated by the reference numerals 46, 48 and 50, so that the on the Electrostatic latent image recorded on photoconductive surface 12 is visualized. In the preferred embodiment, each developer unit is generally known in the art Type labeled "Magnetic Brush Developer Unit". At a

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Typical magnetic brush system is a magnetized ares developer mix used / containing carrier particles and heat-adherable toner particles. In operation, the developer mixture continuously passed through a directional flux field which results in the formation of a chain-like arrangement of fibers extending from extend outward from the developer roll. This chain-like arrangement of fibers is often referred to as a brush. That on The electrostatic latent image recorded on the photoconductive surface 12 is in contact with the brush of developer mixture turned. The toner particles are drawn away from the carrier particles towards the latent image. For example, a green A filtered light image is developed by applying magenta or purple toner particles to it. A red filtered one Photo is filtered with cyan toner particles and a blue one Photo developed with yellow toner particles. This type of development process is called subtractive. A development system of this type is described in U.S. Patent 3,854,449 (Davidson, 1974), the related parts of which are incorporated in the present disclosure be included.

After the solid color electrostatic latent image with toner particles is developed, the drum 10 rotates to the transfer station D. In the transfer station D this becomes electrostatic Toner powder image adhering to the photoconductive surface 12 is transferred to a sheet of carrier material 52. The carrier material 52 may be a sheet of plain paper or a sheet of thermoplastic material, among others. The transmission station D comprises a rrona generator, indicated generally at 54, and a transfer roller, indicated generally at 56 is provided. The corona generator 54 is energized with alternating current and arranged so that it is electrostatically applied to the photoconductive Surface 12 adhering toner powder image is pretreated. The transfer roller 56 keeps the substrate 52 in circulation and is electrically biased to a potential of sufficient magnitude and polarity to electrostatically to the pretreated toner particles of that recorded on the photoconductive surface 12

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to pull the latent image away to the substrate 52. The transfer role 56 rotates in the direction of arrow 58, synchronously with drum 10, around carrier material 52 releasably aligned thereon according to the electrostatic latent image recorded on the photoconductive surface 12. This will it is possible to transfer successive toner powder images onto the carrier material 52, to be precise in alignment with one another. In U.S. Patent 3,838,918 (Fisher, 1974) describes a suitable transfer station and the related parts thereof Descriptions are incorporated into the present disclosure.

The sheet feed mechanism will be briefly described before processing in the remaining workstations. The carrier material is fed from a stack 60 which lies on a tray 62. A feed roller 64 operatively associated with a retard roller 66, feeds and separates the top sheet of the stack 60. The advancing sheet moves in a chute 68 which guides it into the gap between alignment rollers 70. The registration rollers 70 align and guide the sheet Grippers 72 attached to the transfer roller 56. The grippers 72 fasten the carrier material 52 releasably on the Transfer roller 56. After the required number of toner powder images have been transferred onto the carrier material 52, apply the grippers 72 free the carrier material 52 and create a spacing of the same from the transfer roller 56. While the Transfer roller 56 continues to rotate in the direction of arrow 58, is a stripping rod 74 interposed. The carrier material arrives over the stripping rod 74 on a conveyor 76 with endless Belt. The conveyor 76 with the endless belt carries the carrier material 52 on to the fusing station E.

In the fixing station E, which is designed as a melting device and Indicated generally by the reference numeral 78, sufficient heat is generated to cause the transferred toner powder images to be on the substrate 52 to be permanently fixed. A suitable melting point

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direction is described in US-PS 3,781,516 (Tsilibes et al, 1973), the relevant parts of which are incorporated into the present disclosure.

After the fixing process, the carrier material 52 is carried on by conveyors 80 and 82 with endless belts to a collecting tray 84, from which the operator of the device can take the finished color copy from the printer.

It is true that the majority of the toner particles are deposited on the carrier material 52 transferred, but some residual toner particles remain unchanged on the photoconductive surface 12 the transfer of the toner powder image. The residual toner particles are removed from the photoconductive surface 12, as it rotates through the cleaning station F. The residual toner particles arrive in the cleaning station F. under the influence of a cleaning corona generating device (not shown) which is suitable for acting on the residual toner particles and the photoconductive surface 12 remaining electrostatic charge to neutralize. The neutralized Toner particles are then removed from the photoconductive surface 12 by a rotatably mounted fiber brush 86 which is attached to it is in touch, away. A suitable brush cleaning system is described in U.S. Patent 3,590,412 (Gerbasi, 1971).

The foregoing description is sufficient to explain, in connection with the invention, the operation of the improved electrophotographic To explain printing device with the features according to the invention.

Reference will now be made to the particular subject matter of the invention. FIG. 2 shows the coating station B in detail. Lamps 38 and their respective reflectors 88 are arranged to traverse the plate 30 and increasing widths of what is thereon Illuminate composition frame 32. The lamps 38 are

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preferably high-intensity xenon lamps, so that sufficient Illumination is created to project the light image through the screen 44. The lamps 38 are on a suitable cart mounted, which is driven via a pulley system from the drive motor, which sets the drum 10 in rotation. While as the lamp carriage crosses the plate 30, another pulley system moves the lens 34 and the filter 36 at the same speed. The filter group 36 is on a suitable one Mounted bracket extending from lens 34 for movement therewith. The lamps 38, the lens 34 and the filters 36 sense the combined formed on the plate 30 Image to create a flowing light image. As already indicated, optionally a (not shown) Auxiliary lamp used to pass additional light energy through to produce the screen 44 therethrough. The slide projector 20 projects an enlarged image of the translucent color image 18 onto the Mirror 26. The projector 20 is preferably of the Kodak Carousel 750-H type with an F / 2.8 Ektanar C projection lens. However, it can any other suitable slide projector can be used, such as the Kodak Carousel Custom 840-H projector. The projector comprises a light source 22 adapted to illuminate the translucent color image 18 with the lens 24 so arranged is that it produces an enlarged image of the translucent color image 18. The lens 24 has an adjustable Focus to change the magnification while keeping the resulting image in focus. True-to-size or "contact prints" The translucent image 18 can optionally be created by placing the translucent image 18 on the plate 30 is placed. In this mode of operation, the projector 20 is used as an additional source of illumination, with no slide is inserted into this.

The image of the translucent color image transmitted to mirror 26 is reflected on the Fresnel lens 28. The Fresnel lens 28 preferably has the general properties that they made up of small, repeating light deflection elements

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is built, which act as an overall unit in order to achieve a uniform distribution of the light over a predetermined area. The grid or troughs therein are preferably about 200 or more by 2.54 cm (1 inch). The Fresnel lens 28 leads the diverging light rays from the lens 24 of the projector 20 together. Instead of a Fresnel lens, another suitable one can be used Field lens can be used. With such a lens, however, the light rays which produce the image on plate 30 run diverging through. The light rays from the translucent color image and composition frame are passed from mirror 40 through lens 34 and filter 36 are reflected through and form a monochromatic light image. The monochromatic light image is transmitted through mirror 42 Screen 44 reflected through. The screen 44 modulates the monochrome light image and transfers it to the charged part of the photoconductive surface 12. A suitable Fresnel lens 28 is described in detail in U.S. Patent 3,424,525 (Towers et al, 1969), the relevant parts of which are incorporated into the present disclosure.

The filter 36 is set up to include selected color filters in the To provide optical path to produce monochromatic electrostatic latent images on the photoconductive surface 12. Upon reaching At the end of the scan path, the lamps 38, lens 34 and filter 36 are spring biased to begin with return to their original position on the next following cycle. It should be emphasized that the movement of the lens 34, the filter 36 and the lamps 38 at the speed of rotation of the drum 10 to expose the charged part of the photoconductive Surface 12 is in the correct context. For details For the drive mechanism of the optical system, reference is made to U.S. Patent 3,062,108 (Mayo et al, 1962).

The lens 34 is preferably included as an alternating Dagor lens Air gap (split Dagor lens) and has anterior and posterior composite lens components with a centrally located

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between arranged aperture. The lens system generates a high quality image with a field angle of about 31 and a light intensity in the range from about F / 4.5 to about F / 8.5 when magnified 1: 1. In addition, the lens 34 is designed to minimize the effect of the secondary color in the image plane. The front one The lens component has three lens elements with, one after the other, a first lens element designed as a plus lens, one second lens element designed as a minus lens, which is cemented to the first lens element, and a third lens element, which is designed as a plus lens and lies between the second lens element and the diaphragm. The posterior lens component also has three similar lens elements arranged so that lens 34 is symmetrical. With a specific The embodiment of the lens is the first lens element in FIG Front component a biconvex lens, the second element a biconcave lens and the third element a convex-concave lens. For further details regarding lens 34, reference is made to U.S. Patent 3,592,531 (McCrobie, 1971), its related thereto Portions are incorporated into the present disclosure.

Reference is also made to FIG. The filter 36 comprises a housing which is attached to the lens 34 by means of a suitable bracket and moves with it during the scanning of the lens 34 as a unit. The housing of the filter 36 includes a window which is arranged with respect to the lens 34 so that the rays reflected by the mirror 40 can pass through them. The bottom and top walls of the housing include a A plurality of guides extending across the entire width thereof. A filter is movably arranged in each guide. The filters move from an inoperative to an effective position. In the working position, the filter is in front of the window of the housing so that the light rays pass through the filter. The individual filters can be made from any suitable filter material be made such as coated

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Glass. In the preferred embodiment of that shown in FIG Electrophotographic printing machine uses three filters, namely a red, a blue and a green filter. Each the filter is assigned to the correspondingly colored toner particles, i.e. the associated complementary color to a subtractive System to generate. A green filtered light image is developed with magenta or purple toner particles, a red filtered one Photo with cyan toner particles and a blue filtered photo with yellow toner particles. A detailed description of filter 36 is found in U.S. Patent 3,775,006 (Hartman et al, 1973), the related parts of which are incorporated in the present disclosure be included.

The screen element 44 is a in the preferred embodiment arcuate element with a curvature substantially equal to the curvature of the drum 10. To achieve this, the Screen member 44 may be a flexible, translucent sheet having a plurality of spaced, opaque lines thereon. The curvature of the screen element 44 is equal to the curvature of the drum 10, the radius of curvature of the screen element 44 being greater than the radius of curvature of the drum 10. The centers of curvature of the screen member 44 and the drum 10 coincide to set a suitable distance therebetween. The umbrella element 44 is located in the printing device by means of a suitable frame attached thereto, e.g. a pair of side rails, which ensure a uniform distance between the screen element and the photoconductive surface 12.

In the preferred embodiment, the screen member 44 comprises a flexible, substantially translucent sheet made of a suitable plastic material, for example Mylar. However, the person skilled in the art will readily recognize that a preformed material, for example glass, can be used. A plurality of spaced, opaque lines are on the transparent sheet. The screen member 44 includes a plurality of lines printed on the transparent sheet

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by means of suitable chemical etching or another suitable one photographic technique. The screen itself can be made from any number of opaque metal materials suitable for chemical etching and thin enough to be flexible, such as copper or aluminum. The distance between adjacent lines determines the quality of the resulting copy. A finer screen results in the generally a more natural or higher quality copy. Thus it is a relatively coarse screen with 50 to 60 lines on 2.54 cm (1 inch) suitable for some purposes, finer umbrellas with anywhere from 100 to 400 or more lines over a distance of 2.54 cm (1 inch), however, will produce a copy with an almost continuous appearance of tint. With finer umbrellas, the umbrella pattern can be barely noticeable on the finished copy, and the copy has the appearance of a photograph with continuous tint. at In a preferred embodiment, the screen has about 120 lines for a distance of 2.54 cm (1 inch).

The radius of curvature of the screen member 44 is preferably about 0.254 cm (0.1 inch) greater than the radius of curvature of the drum This defines the distance between the screen element 44 and the drum 10.

In the preferred embodiment of the invention, a curved screen is used, but those skilled in the art will readily recognize that a flat screen can also be used. Flat umbrellas can be formed from a translucent sheet having a plurality of spaced opaque lines thereon having.

In summary, it should be noted that the electrophotographic printing machine shown in Figure 1 is suitable for opaque Making color copies from translucent color images. The translucent image can be true to size or can be copied enlarged. In addition, a compositional

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frames can be combined with or without information on them. The translucent color image can be a conventional 35 itim slide or any other microfilm. This is achieved by projecting an image of the translucent Color image through a Fresnel lens and a composition frame that lies on the plate of the printing device. The scanning system of the printing device produces a filtered combined image from the translucent color image and the composition frame. The filtered combined image is projected through a screen and results in a modulation thereof that corresponds to the charged image Part of the photoconductive surface is irradiated. This records a single color electrostatic latent image thereon, which is developed with toner particles that are complementary in their color to the color of the filtered light image. Consecutive monochromatic electrostatic latent images are developed with appropriately complementary colored toner particles. the Toner powder images are aligned apart and transferred onto a sheet of carrier material, forming a multi-layered one Toner powder image. The multi-layered toner powder image becomes permanent on the sheet of carrier material by means of a melting device fixed. The resulting color copy is removed from the printing device and corresponds to a combined image of composition frame and translucent color image.

Thus, the invention provides an electrophotographic printing machine created that fulfills the aforementioned task. It should be emphasized that the invention is based on a particular embodiment has been described, but many modifications and changes are made to the principle on which the invention is based can.

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Claims (10)

Claims 1/. Electrophotographic printing machine for reproducing a translucent color image, characterized by a photoconductive element (12), means (16) for charging the photoconductive element (12) to a substantially uniform level, a filter device (36), a screen element (44) disposed closely adjacent to the photoconductive element (12), and means for projecting a light image of the translucent Color image (18) through the filter device (36) and the screen element (44) to form a modulated monochromatic light image for the selective dissipation of the charged part of the photoconductive element (12) for recording a single color electrostatic latent image thereon. 2. Printing device according to claim 1, characterized by a receiving element, an opaque document resting on the receiving element is arranged, and means for exposing the charged portion of the photoconductive Element (12) with a light image of the opaque document for recording a combined electrostatic latent image thereon, the single color electrostatic latent image of the translucent color image and the electrostatic includes latent image of the opaque document. 3. Printing device according to claim 2, characterized in that the projection device is the light image of the translucent color image transmits through the receiving element. 609885/1008 4. Printing device according to claim 3, characterized in that the opaque document comprises a composition frame (32), which defines an opaque edge which extends from the image of the translucent one formed on the receiving element Color image extends outward. 5. Printing device according to claim 3 or 4, characterized in that the projection device is arranged on the printing device Has slide projector (20) for projecting an image of the translucent color image lying thereon onto the receiving element. 6. Printing device according to claim 5, characterized in that the receiving element has a translucent plate element (30) on which the opaque document is disposed, and comprises a Fresnel lens (28) resting on the opaque document is appropriate. 7. Printing device according to one of claims 3 to 6, characterized in that that the exposure device is one for illuminating the opaque document lying on the receiving element arranged light source (22, 38) and a lens device (34) for receiving the light rays from the combined image the translucent color image and the opaque document. 8. Printing device according to one of claims 2 to 7, characterized by means (C) for developing the electrostatic latent image recorded on the photoconductive member (12) Toner particles, means (D) for transmitting the said electrostatic toner powder image adhering to the latent image from the photoconductive element (12) onto a sheet of carrier material (52) and means (78) for fusing the toner powder image onto the sheet of carrier material (52). 609885/1008 9. Printing device according to claim 8, characterized in that the
A screen member (44) comprises a transparent sheet having a plurality of spaced apart opaque lines thereon. 10. Printing device according to one of claims 1 to 9, characterized in that the photoconductive element (12) is arcuate and
the screen member (44) has an arcuate portion with a curvature substantially equal to the curvature of the photoconductive element
(12), wherein the centers of curvature of the photoconductive element (12) and the arcuate part of the screen element (44) substantially coincide with each other, and that the arcuate Part of the screen element (44) has a radius of curvature which is greater than the radius of curvature of the photoconductive element (12), which sets a distance between them. 609885/1008