DE1943502B2 - ELECTROPHOTOGRAPHIC PROCEDURE - Google Patents

Description

The invention relates to an electrophotographic process in which on a photoconductive Recording layer with an η-conductive photo semiconductor such as a metal oxide semiconductor, which is on a electrically conductive substrate is applied by uniform, negative charging and imagewise Exposing a latent charge image is generated.

The well-known method of electric photography is the so-called electrofax method in which Zinc oxide is added to the photosensitive layer. With the electrofax process, the surface is on negatively charged in an unlit place, after which exposure is made. The charging of the The surface of the photosensitive paper is due to the photoconductive nature of the photosensitive Layer reduced accordingly. The exposure is interrupted when the difference in charges the surface of the photosensitive paper is largest. The latent image is then on the light-sensitive paper easily fixed.

This phenomenon will be explained later with the aid of the diagram in FIG. 1 explained in more detail. The negative Static charge that is evenly transferred to the photosensitive paper by the corona discharge has the property that it is only slightly in the dark part of the image during the exposure time is diminished while in the light part at the beginning

ίο the exposure only a little, but then suddenly steep drops after the amount of light has exceeded a certain value, after which the potential in Depending on the exposure time, it falls essentially uniformly down to zero. The contrast of the latent image is determined by the difference in the amount of charge corresponding to the shade of the image generated on the surface of the photosensitive layer.

At the beginning of the exposure there is hardly any contrast between the light and dark part of the picture achieved because the drop or the slope of the two curves (see Fig. 1) is low. The during this Exposure carried out over time therefore does not contribute to the formation of contrast in the latent image. Only this increases the exposure time. In addition, it can lead to incorrect playback, if the exposure time was not correctly specified.

The object of the invention is to provide an electrophotographic To develop a process in which the exposure time of the imagewise exposure shortened as well as the for Exposure required amount of light is reduced while the quality of the reproduction remains the same.

According to the invention, this is achieved by uniform irradiation before the imagewise exposure of the recording material takes place in such a way that the subsequent imagewise exposure in the bright Image splitting results in a straight, temporal course of the potential drop.

Negative charging and the pre-irradiation of the photoconductive recording material with light can take place at the same time, after which the actual exposure is carried out.

The η-conductive photo-semiconductor (N-type photo-semiconductor) preferably consists mainly of zinc oxide, and the ratio of those applied to the photoconductive recording material by the pre-irradiation Amount of light to that produced by the actual exposure on the area corresponding to the bright parts of the image of the photoconductive recording material is applied, can be 1/3 to 1/10.

The pre-irradiation is preferably carried out with lOlxs and the exposure with 40 Ix s (Ix s = lux second).
In a device for carrying out the method, a pre-irradiation lamp, preferably a tungsten filament lamp, is arranged between the known charging device and the plate on which the photoconductive recording material, preferably paper, lies for exposure

bo photoconductive recording material exposed to uniform irradiation and the exposure process can be carried out unhindered by an optical system known per se.

Further details of the method according to the invention

M ren and the associated device are explained with reference to the drawings. It shows

1 shows a diagram with the potential drop curves in the dark and light parts of the image and

2 shows a schematic representation of a device to carry out the procedure.

Before explaining an exemplary embodiment of the device according to the invention, the principle for creating an electrostatic latent image in electronic photography will be described, a material that becomes electrically conductive when incident light (N-type photoconductive material) is used as the photosensitive element. In the electrophotographic process for taking an image, zinc oxide is used on the electrophotographic paper and the surface of the paper is uniformly charged to a potential of Vs volts in advance. If this paper is then irradiated or exposed, the part of the photosensitive paper on which the dark part of the original, e.g. B. black characters, are shown, a certain potential drop (dark decay). This drop is shown in FIG. 1 as the curve a falling with a slight incline, the surface potential (V) being plotted on the ordinate axis and the exposure time (T) being plotted on the abscissa axis. The part of the paper on which the light parts of the original, namely the transparent and white parts, are shown also shows a drop in potential, but of a different kind, the course of which is the steeply sloping curve b in FIG. 1 corresponds.

The difference between the surface potential of curves a and b at a specific exposure time corresponds to the contrast of the electrostatic charge of the latent image corresponding to the shade of the original. Therefore, when the potential difference is the greatest, the contrast of the electrostatically charged latent image also becomes the greatest, and the exposure time is correct at this time.

As can be clearly seen from FIG. 1, the slope of curve b and thus the potential drop (decrement) at the beginning of the exposure process is small, so that there is no significant difference from curve a and no great potential difference. This suddenly changes with the exposure time fi, after which there is a steep drop in curve b . Such a property is found in metal oxides, especially zinc oxide, which is explained as follows: When the photoelectric material, which consists mainly of metal oxide such as zinc oxide (ZnO), is negatively charged, the negatively charged oxide molecules are brought to the surface. If the material is then exposed to light rays, pairs of electrodes and holes (defect electrons) are generated in the light-sensitive material. The resulting holes are filled or neutralized by the negatively charged oxide molecules, while the electrons flow to the electrode. This flow of current, the so-called photocurrent, causes the surface potential of the electrophotographic paper to drop. Since the oxide molecules are very strongly electronegative, the luminous flux does not start immediately. After the Oxydmolekül lost by the neutralization of its electronegativity, it escapes to by the loss of the thermal equilibrium of the surface of light-sensitive paper in the air and the so-called light-induced discharge is caused. In this case the electrons are not released to flow to the electrode, and the surface potential only begins to decrease when the so-called light-induced charge begins. In this way, a curve like curve b of curve F i g. 1, received.

The value of the time that has elapsed to t \ varies depending on the structure and composition of the light-sensitive zinc oxide layer, but this time to t \ is noticeable with the paper (axpaper) used up to now. This time span U corresponds to the correct exposure time from 1: 4 to 1: 3.

Since the potential drop at the beginning of the exposure time up to h is small, regardless of the shading of the image, and thus also the difference in the potential drop in curves a and b , the exposure up to time t \ is almost ineffective, so that the time t \ is an unnecessary extension the exposure time. As in conventional photography, the more the curve b approaches a straight line, the better the electrostatic latent image corresponds to the image of the original. The greater the start-up time / 1, the lower the imaging fidelity of the latent image.

The invention has therefore set itself the task of reducing the (imagewise) exposure time by the span f | To shorten. The inventive method for creating or recording an image consists in that the entire surface of the photosensitive paper is irradiated after the charging process until the potential drop corresponds to the abscissa value t \ , whereupon the actual image exposure begins.

According to the invention, the exposure time with a light source of large capacity is shortened in that the Paper is initially uniformly irradiated by a light source of low capacity close to the paper, after which only the actual exposure using an imaging lens system with a Light source of large capacity takes place. In this way it is possible to reduce the consumption of electrical power and prevent overheating of the large capacity light source for image exposure.

An experiment in connection with the present invention is explained below. In an electrofax copier using a xenon flash lamp as the light source for exposure, two lamps were used A power consumption of 150] ouls is used for the image exposure and the exposure in the usual way performed. A correct exposure of 50 Ix s (Ix s = lux second) on the bright part of the Picture given. But instead of the lamps mentioned, two lamps with a power consumption of 100 joules under the same conditions, namely the same original to be scanned, the same photoelectric Paper and the same exposure time were used, the surface potential drop was of the part of the electrophotographic paper corresponding to the light part of the image is insufficient and the exposure undoubtedly too short. After but according to the proposal according to the invention the same light-sensitive paper is irradiated evenly with a tungsten lamp of 10 Ix s and before exposure was then exposed with the same lamps of 100 joules at the same exposure time, that was Surface potential of the part corresponding to the bright part of the image is zero and an image preserved with good contrast.

According to the invention, the entire surface of the uniformly negatively charged photosensitive paper is irradiated before the actual exposure, so that the amount of light corresponding to the start-up time t \ is applied to the photosensitive paper in advance. The paper can also be irradiated in one operation with the image exposure

will. It is only essential that the exposure takes place after the irradiation. In this case the light source must be be arranged for irradiating the paper so that the image exposure is not obstructed.

In Fig. 2 an apparatus for carrying out the proposal according to the invention is shown. The photosensitive paper 1 has a photosensitive layer Γ of uniform thickness made of a synthetic resin mixed with zinc oxide powder. This layer is uniformly negatively charged as the paper passes through a corona charging device 2. A tungsten filament lamp 3 with a screen 4 which is open in the direction of the paper irradiates the light-sensitive layer Γ passing it uniformly and brings that of time i | corresponding amount of light of about 10 Ix s. If the paper comes to a standstill at the image exposure point 5, the original 7 on the transparent plate 6 is exposed by the light source 8 and the original 7 is imaged onto the photosensitive layer Γ via the mirror 9 and the lens 10, the light source being designed in this way that the part of the light-sensitive layer Γ corresponding to the bright part is exposed to an amount of light of 40 Ix s corresponding to that applied in the time t - t \. In the device according to the invention, it is necessary to arrange the light source for irradiation in such a way that first the uniform irradiation takes place and only then the exposure is carried out without this being hindered by the irradiation lamp.

In the embodiment described, the paper is sensitive to light during the movement charged and also irradiated while it is exposed in still stanc. A movement of the paper is also possible possible, provided that the original is also moved accordingly. It is also possible to have the paper inside: Bring every process to a standstill.

1 sheet of drawings

Claims (5)

Patent claims: 1. Electrophotographic process in which on a photoconductive recording layer with an η-conductive photo semiconductor such as a metal oxide semiconductor, which is based on an electrically conductive Layer carrier is applied by uniform, negative charging and imagewise exposure a latent charge image is created thereby characterized in that before the imagewise exposure a uniform irradiation of the Recording layer of the kind takes place that the subsequent imagewise exposure in the bright Image splitting results in a straight, temporal course of the potential drop. 2. The method according to claim 1, characterized in that the negative charge and the Pre-irradiation of the photoconductive recording layer with light takes place simultaneously and then the actual exposure is carried out. 3. The method according to claims 1 or 2, characterized in that the η-conductive photo semiconductor consists mainly of zinc oxide that the ratio of the pre-irradiation to the photoconductive recording layer applied amount of light to that caused by the actual Exposure on the area of the photoconductive recording layer corresponding to the bright parts of the image is given up is 1/3 to 1/10. 4. The method according to claims 1 to 3, characterized in that the pre-irradiation with 10 Ix s and the exposure takes place at 40 Ix s. 5. Device for performing the method according to one of the claims! to 4, thereby characterized in that between the known charging device and the exposure point (5) on which the photoconductive recording layer (1), preferably with a paper support, for Exposure rests, a pre-irradiation lamp (3), preferably a tungsten filament lamp, so arranged is that the photoconductive recording layer (1) is exposed to uniform irradiation and to carry out the exposure process unhindered by an optical system known per se is.