DE1671522C3 - Process for producing a charge image - Google Patents

Description

The invention relates to a method for producing a charge image by imagewise charging a neutral or imagewise discharge of a homogeneously charged insulating recording material.

Electrographic processes are known, according to which insulating recording layers with the help imagewise shaped electrodes are printed with charge images. Another known method consists in generating the charge image with an electrode, which consists of a large number of individual elements arranged in a grid-like manner and isolated from one another, these individual electrodes in a combination corresponding to the intended pressure applies.

Processes are also known according to which an imagewise charge of insulating recording materials is generated in a discontinuous manner using photoconductors. Here the Charge transfer from the photoconductor to the recording material takes place through an air gap between the photoconductor serving as the charging electrode and the surface of the recording material. Shock-like charge transfers that cause blurring cannot be avoided under these circumstances.

A disadvantage of this method is, on the one hand, the considerable technical effort involved in the production of Images with preformed electrodes and, on the other hand, the unsatisfactory reproducibility of the rest Recording method, which is due to the fact that the ignition of each discharge is strongly external Influences, such as temperature and humidity, depends. The one mentioned last

The method also has the disadvantage that the intermittent discharges create a spotty structure of the developed image, thereby increasing both the resolution and the reproduction of Halftones are affected.

From US-PS 32 20 324 it is known on a insulating recording material to generate a charge image by means of a corona current. The Charge current through a photoconductive material coated and imagewise exposed grid electrode differentiated image by image

The use of a grid electrode as a controlling element for the imagewise charging of the recording material has the disadvantage that for the passage of the charging current a certain minimum mesh size is required, which in turn is a limitation of the Image sharpness is also disadvantageous are the relatively high voltages used to control the Charging of the image carrier required by the field between the grid electrode and the recording medium that are. As a rule, the grid must have the full Charging voltage, e.g. 200 to 300VoIt, can be generated on the grid in a differentiated manner in terms of image.

It is also known (US-PS 32 70 637J, clektroviscose liquids for the production of records on any surface, e.g. B. paper to use. For the application of electroviscous liquids nozzles are used that allow the passage of liquids to be controlled by generating electrical fields that reduce the viscosity of the Increase or decrease fluids. The main disadvantage of this recording method is its and the inertia caused by the use of more or less viscous writing fluids achievable relatively low resolution in the record tion.

The invention is based on the object of providing a relatively fast and technically simple electrographic method for recording charge images with high resolution on an isolating of the recording material to develop.

The invention relates to a method for producing a charge image by imagewise Charging of a neutral or imagewise discharging of a homogeneously charged insulating record voltage material by means of one of a time constant held corona discharge generated and modulated by an image-wise differentiated electrostatic field corona ion current, which is characterized in that the corona ion current by an between the metal screen arranged on the corona ion source and the recording material is differentiated image-wise, which has a gap for the passage of the corona ions in its area an image-wise differentiated Control field is generated, and that between the Metal shutter and the back of the recording material is applied a voltage that is less than that is the breakdown voltage applicable to the air layer in between. According to one embodiment of the invention, the

H"; Recording material charged imagewise by a constantly maintained corona current. Part of the Corona currents are generated from a discharge electrode through the gap in a metal screen.

de onto the surface of the recording material steered while in the gap by electrical charging of one arranged on one of the gap lips Photoconductor strip, an electrical transverse field is generated. This cross-field is created by a pictorial Differentiated exposure of the photoconductor strip, i.e. permeable or impermeable to the corona current made, which corresponds to a picture-wise control of the corona flow. It is also possible here that Potential of the photoconductor through an auxiliary electrode embedded in the photoconductor strip on the one for image recording to set the most favorable value.

In a further embodiment of the invention, the photoconductor strip acting as a control element is used replaced by a flat bundle of line-like, conductive elements, over which the transverse field through electrical signals can be controlled, for example by video signals or by voltage pulses, which are used for the transmission of measured values.

The method according to the invention has compared to the method which works with a grid electrode The advantage of building the control field in the gap in the metal screen is that the control voltages are considerably lower are required than to control the charging of a recording medium by a field between a Grid and the recording medium. While according to the known procedure, the full charging voltage, z. B. 200 to 300 volts, image-wise differentiated must be generated on the grid, it is possible in the Application of the gap according to the invention, the suction tension between the slit diaphragm and the recording medium to keep constant at this level and higher. The control voltage in the gap can be between 20 and 30 volts include the full tax scope. This gives a gain by a factor of 10.

The essence of the invention is described in more detail below with reference to the drawing. In detail shows

F i g. 1 the principle of the method according to the invention using the example of a simple embodiment,

F i g. 2 shows another embodiment of the method with sliding exposure of the photoconductor strip,

3 shows an expedient design of the discharge electrode (1),

F i g. 4 and 5 show two cross sections of control electrodes as exemplary embodiments for the preparation of the Cleft lip with a photoconductor,

F i g. 6 a control electrode that replaces the photoconductor strip has a plurality of conductor elements

F i g. 1 shows the principle of the method according to the invention. At the discharge electrode 1, which can be designed as a thin wire or as a series of metal tips, a corona is generated by applying a voltage from the high-voltage source 2, from which a current of charge carriers passes to the metal screen 4 and a partial current passes through the gap 5 reaches the recording material 6, where a line-shaped or strip-shaped charge 7 arises in accordance with the shape of the gap. The recording material, e.g. B. a plastic-coated paper is held by the metal plate 8 to be earthed. To facilitate the passage of charge through the gap 5, suction voltage is applied to the diaphragm 4 and the plate 8 and is taken from the voltage source 9. The height of the suction voltage is such that an optimal charge of the recording material 6 is given, but that no flashovers or excess charges take place from the diaphragm over the surface of the recording material,

A lip of the gap 5 is covered with a strip-shaped photoconductor 10. On the unexposed one Due to its relatively high dark resistance, the photoconductor is affected by the incident charge carriers Potential built up, which creates an electric field across the gap, which is generated by the field lines 11 is indicated If such a transverse field is present, then the charge carriers hitting the gap opening are laterally deflected and taken up by the aperture. This causes the recording material to be charged 6 prevents In the exposed state of the photoconductor, its conductivity is sufficient to achieve the to divert the sprayed charge carrier to the screen, and no cross-field is generated in the gap 5 It depends that is, on the exposure of the photoconductor 10, whether the recording material 6 is charged or not. Now can be achieved by the exposure of only a part or several parts of the strip 10 that the Line charge on the recording material 6 only partially arises, for. B. corresponding to a narrow Zone across an exposed optical image. The image line is then on the recording material as Line of a charge image reproduced.

As in Fig. 2, it is now possible to go through a displacement of the diaphragm 4 in one of the directions indicated by arrows a resting, in the slit plane projected image with the gap 5 of the diaphragm 4 to be scanned over the entire cross-section and as a charge image to be transferred to the recording material 6. This charge image is then generated in a known manner made visible through concrete. The optical image can also be scanned in such a way that the diaphragm 4 is held, but the projected image and the recording material 6 are moved further in synchronism will.

To improve the spray properties of the discharge electrode 1, it is advantageous to use it with a To surround metal shield 12 (Figure 3), which is placed over the gap 5 on the panel 4. the The shield is open at the top and bottom so that the gap 4 is exposed from above knows can.

The higher the demands on the resolution of the image to be developed, the narrower it should be Photoconductor strips 10 can be formed, thus also through small areas of the projected image conductive bridges made from the edge of the photoconductor strip to the connection to the metal panel and the charges can be discharged at these points. But the narrower the strip 10 becomes, the less is the charge on the surface of the strip in the unexposed state and thus the controllability of the photoconductor.

Dc moch you can with extremely narrow photoconductor strips work, if the photoconductor strip is equipped with an additional electrode, to the auxiliary voltage can be created, through which the control potential adjust to the desired level Expedient embodiments are shown in FIG. 4 and 5.

In Fi g. 4 is the part of the aperture that holds the photoconductor carries, designed as a plastic rail 12, which is worked out to a step 1 13 at the edge. Of the The recessed part is filled with the photoconductor 10 in the form of a bar with a qi-adratic cross section. The top of the bar is covered by a dashed conductive belae 14. which goes up to just before the edge of the

Bar 10 is pulled. so that only a very narrow strip remains uncovered with the metal body 4 of the Aperture connected. In the exposed state of the photoconductor, the charge is transferred over this coating discharged. The charge is supplied and the potential is maintained in the dark through the lead wire 15 embedded in the photoconductor. The edge thus prepared forms a lip of the Gap 5. The second lip 16 of the gap is made of metal and is opposite the free edge of the Phuto conductor 10 arranged.

F i g. 5 shows another embodiment of the control electrodes, in which the recess of the plastic rail 12 is filled by the photoconductor 10 so that the cross-sectional area represents a triangle, one edge of which with the opposite metal strip 16 den Gap forms.

Control electrodes of the type shown in FIGS. 4 and 5. which are equipped with auxiliary electrodes no longer require the corona current for charging. since the transverse field in the gap can be set arbitrarily with the auxiliary electrode by applying a suitable auxiliary voltage. In this form, the control electrode is also suitable for operation with alternating voltage. If an alternating voltage of sufficiently low frequency is used as the auxiliary voltage. 7. B. 50 Hz. This creates grid-like charge structures on a carrier that is moved relative to the gap, which charge structures can be advantageous for the exclusive development.

The control of the charging current is also possible in that the preparation of a gap lip with the Photoconductor is replaced by an arrangement of line-like conductors 17 at the gap 5 of the diaphragm 4 in Fig. 6. via which voltage pulses or tax savings can be applied for image recording. This control electrode can, for. B. as flat wire bundles or metal supports printed on plastic in the manner of Circuits be formed. A connection to a scanning element can be established via the conductor elements greater distances can be established, for example for the purpose of transmission and recording of Images or measured values.

In the with F i g. I to 6 described devices the gap width is a few tenths of a millimeter, preferably 0.2 to 0.5 mm. The distance between the bezel 4 from the surface of the recording material 6

s is a few millimeters, preferably 1 to 2 mm. The control voltage at the edge of the gap is in the range from 0 to 1000 V., preferably 0 to 300 V. The suction voltage between cover 4 and base 8 is optimally set so that a disruptive charge transfer

in does not yet occur from the diaphragm to the carrier surface. It is a few k-volts. The corona at the discharge electrode 1 is generated in a known manner, whereby the optimal tension is to be set according to the geometrical relationships of the arrangement.

π Of course, the inventive Ver drive is also used for the imagewise discharge of a homogeneously precharged recording material be, with the corona flow either a buuwcisc Ncuii

VurnariuCncn Charges or a further imagewise charging of the recording material with the reverse Causes sign.

The method according to the invention has decisive advantages over the conventional methods which i.a. consist in the fact that image recordings are possible with the simplest electrode arrangements and the desired effect is achieved with the least amount of equipment. Furthermore, through the extensive Insensitivity of the recording quality to the distance between the control electrodes and the surface of the recording material also the use of papers with a not completely flat surface ah Recording medium possible. This makes it possible to develop several extracts on top of each other Images given in different colors, as an isolating clay already applied to the paper a second imagewise charge is not impaired. The electrode gap can always be kept as large be that a blurring of an already existing one

■ »ο the toner image does not appear. Further advantages lie in the Operational reliability of the process and the ability to apply image charges in a continuous manner gene.

1 sheet of drawings

Claims (3)

Claims; 1. Method for producing a charge image by imagewise charging a neutral or imagewise discharge of a homogeneously charged insulating recording material by means of a Corona ion current generated by a corona discharge kept constant over time and modulated by an image-wise differentiated electrostatic field, characterized in that, that the corona ion flow through one between the corona ion source and the recording material arranged metal screen is differentiated image-wise, which a gap for the passage of the Has coronaions in the area of which an image-wise differentiated control field is generated and that between the metal shutter and the back of the recording material, a voltage is applied which is less than that for the intermediate air layer is the applicable breakdown voltage 2. Apparatus for performing the method according to claim 1, characterized in that for Generation of the image-wise differentiated control field along one of the cleft lips from a strip photoconductive material is arranged, which is in the insulating state by the charge carriers of the Coronastromes is charged and loses its charge due to exposure. 3. Apparatus for performing the method according to claim 1, characterized by a Arrangement of line-like conductor elements, which en-Ien on one of the lips of the spook and over that of outside image-wise differentiated control voltages can be applied to the gap ι.