EP0059514A2 - Method and device for the electrophotographic presentation of information - Google Patents

Abstract

Method for the electrophotographic display of an electrically stored information with a cathode ray tube. This tube is controlled in such a way that only one raster line of information on the screen is activated several times in succession. Therefore, the transport movement of the record carrier takes place continuously. The optical system provided between the cathode ray tube and the recording medium can be rigid, so that a raster image is formed on the recording medium, the individual raster of which represents a small line consisting of several overlapping points. The required brightness is achieved by using a cathode ray tube with a wide screen on which the raster line to be transferred to the recording medium is imaged on a 1: 1 scale. Furthermore, the screen is coated with a coarse-grained phosphor of the zinc sulfide type, which has a high luminous efficiency. In addition, the line frequency of the cathode ray is increased to the usual extent in order to counteract phosphorus saturation.

Description

The invention relates to a method and an arrangement for the electrophotographic representation of an electrically stored information with a cathode ray tube, the luminous layer of which is covered line by line by a cathode ray in accordance with the stored information, and with a photoconductive recording medium, on the photoconductive layer of which is activated by the activated luminous layer of the cathode ray tube Optical system a mosaic-like latent charge image is created, which is then transferred to another record carrier, the minimum line frequency with which the cathode beam is deflected corresponds to the quotient of the feed speed of the record carrier and the line spacing.

From DE-OS 24 12 360 an electrophotographic device is known in which the illuminated dots of a character to be displayed on the screen of a cathode ray tube are optically transmitted to a recording medium via an optical system consisting of mirrors and lenses. The entire character of the character is recorded on the screen in a grid pattern and transferred to the recording medium. For this purpose, the electron beam of the tube has to be deflected horizontally and vertically. In order to keep the tube small in size, the individual luminous dots are smaller than the raster dots to be recorded on the recording medium, so that the luminous dots to be transmitted must be enlarged by the optical system. But this also increases all blurring of the luminous dots, so that there is a blurred imprint of the image to be recorded on the recording medium. In addition ver As a result, the luminous dot to be transmitted loses significantly more brightness. An increase in the beam current of the cathode ray tube can somewhat alleviate these disadvantages but cannot avoid them. Another disadvantage is that the record carrier has to be stopped by the cathode ray tube during character transmission. It must therefore be transported in start-stop mode. This means a relatively high energy consumption and a large technical effort, which is subject to high wear.

Furthermore, from DE-OS 30 14 356 an electrophotographic printer is known in which the screen of the cathode ray tube is equipped with optical fibers which transmit the activated luminous image directly to the recording medium and without a special optical system. However, since the developer cannot contaminate the optical fibers and the risk of damage means that they cannot be brought close to the recording medium, this also results in a scattering of the light point to be transmitted and thus a low resolution of the latent image on the recording medium. In addition, this arrangement has the disadvantage that a precise positioning and tracking mechanism is required to maintain a small constant distance between the optical fibers and the recording medium.

The invention has for its object to provide a method and an arrangement for the electrophotographic representation of characters and images with which the individual light points of the cathode ray tube can be generated with a relatively small beam current and still have a sufficiently good brightness bypassing the use of contact exposure by optical fibers so that a latent image with good resolution is obtained on the recording medium.

This object is achieved by a method in which each individual raster line of the same information content of the mosaic-like charge image to be recorded is generated separately by the cathode beam controlled according to the stored information on the screen of the cathode ray tube and transmitted to the recording medium by means of an optical imaging system and recorded there and in which this cathode beam passes over the same raster line on the screen several times in succession with a line frequency that is higher than the minimum line frequency, the recording medium being moved continuously.

Since the record carrier is moved continuously, the activated luminous dots of the cathode ray tube are shown vertically shifted on the record carrier with each subsequent scan. Thus, no individual points are created, but rather small lines formed from several overlapping points. The length of these lines depends on the number and speed (frequency) of scanning the cathode ray over the same line and on the transport speed of the recording medium.

To achieve a greater brightness of the luminous dots and a better resolution, the luminous dots of the raster line are displayed on the screen in the size of the raster dots to be imaged on the recording medium.

The optical system used therefore only has the task of deflecting and focusing the light rays emitted by the screen onto the recording medium without enlarging the grid pattern, so that a "1: 1 transmission" from the cathode ray tube to the recording medium takes place.

A cathode ray tube is used to carry out this method, the screen of which is very low and the height of which is therefore considerably smaller than its width. In this case, only a single deflection system is provided, which deflects the cathode beam horizontally. In this case, by repeatedly covering the light spot area with the same raster line on the recording medium, a small vertical line formed from a plurality of overlapping raster points is generated as a raster, which the human eye will practically regard as a point.

Furthermore, since it is not necessary to enlarge the luminous dots to the predetermined raster dot size, the screen can be coated with a relatively coarse-grained, highly efficient luminous phosphor.

• Fig.1 den prinzipmäßigen Aufbau eines elektrophotografischen Druckers,
• Fig.2 die perspektivische Ansicht der Kathodenstrahlröhre und
• Fig.3 ein Diagramm der Lichtleistung der Kathodenstrahlröhre bei verschiedenen Zeilenfrequenzen.

The invention is explained in more detail below using an example. Show it:

• 1 shows the basic structure of an electrophotographic printer,
• 2 shows the perspective view of the cathode ray tube and
• 3 shows a diagram of the light output of the cathode ray tube at different line frequencies.

An electrophotographic printer is shown in FIG. All the necessary structural units are accommodated in a housing 17. With the help of a cathode ray tube 8, which is connected with its connection 11 to the associated electronics (not shown), digitally stored alphanumeric or graphic information is made visible on its screen 9 and this optical light image via an optical system that consists of the mirrors 12 and 14 and the lens 13 is transferred to an endless recording medium 1, for example a drum or tape, with a photoconductive layer. This creates a latent charge image in the recording area 15 on the recording medium 1 which corresponds to the information to be recorded. The record carrier rotates continuously in the direction of the arrow. The latent charge image is developed in a developer station 2 and transferred to a normal paper 4 in the transfer station 3. This paper 4 is withdrawn from a removal compartment 5 and after the transfer of the latent image and its development and fixing in the fixing station 18 in one Storage compartment 6 filed. After the transfer, the recording medium 1 is cleaned and cleaned of the latent image in the cleaning station 7.

A tube shown in FIG. 2 with a quite flat rectangular screen 9 with a length L of approximately 210 mm is used as the cathode ray tube 8. This corresponds approximately to the width of an A4 page. The height H is approximately 20 mm. The cathode ray deflected only horizontally by the deflection system 10 sweeps a red dot area 16, the height of which corresponds approximately to the diameter of the halftone dots that are to be recorded on the recording medium 1. Only one raster line of the information to be displayed is always displayed in this area. A raster line is understood to be a raster dot line of all characters to be printed on the A4 page. The same raster line display is shown several times, preferably at least three times, on the screen 9, ie the illuminated area is covered several times with the same line content by the cathode ray. The beam can either activate the illuminated dot area 16 either in the same direction or during forward and backward deflection _M ehrfachdarstellung same raster line information happens to the line frequency, thereby increasing the sweep speed of the electron beam in the tube. With an increased deflection speed (= light spot speed ν on the screen), the saturation of the luminous phosphors on the screen of the tube is alleviated. As a result, a greater brightness of the phosphor layer of the screen 9 is achieved, so that the latent image recorded on the recording medium 1 is more intense.

The screen 9 of the cathode ray tube 8 is covered with a highly efficient phosphor layer, e.g. with a zinc-cadmium sulfide to which copper has been added. Such a layer achieves a high brightness of the luminous dots with a relatively low beam current of the cathode ray tube. In contrast to the known phosphors used in electrophotographic printers, the luminous efficiency of the phosphor used is 15% instead of only 2 to 5%.

The ZnS-type phosphors have a high luminous efficiency with a small beam current, but they reach the saturation range very quickly as the load increases. However, this range can be shifted very far towards high beam currents by increasing the line frequency. This will reduce the recording speed slightly, but more. Controlling the tube several times with the same information content, namely with a certain raster line, results in an undistorted reproduction of the information.

The invention was tested in a model, based on the following values:

von etwa 60 mW. Dieser Leistungsbedarf P' ist in dem Diagramm der Fig.3 gestrichelt eingetragen.These values resulted in a light power requirement P according to the formula

of about 60 mW. This power requirement P 'is shown in dashed lines in the diagram in FIG.

With a line spacing of 0.1 mm, the minimum line frequency V is 1.65 kHz, that is to say when the illuminated dot area is swept once, 16 per raster line (lower curve in FIG. 3). It was shown that the desired light output P 'could not be achieved. On the other hand, if the line frequency ν was increased by a factor of 3, ie covering the same light spot area 16 three times, there was a frequency of 4.95 kHz with a luminous efficacy of 60 mW. All that was required was an anode current Ia of 43 _/ uA (middle curve in FIG. 3). With a further increase in the line frequency ν by a factor of 6, ie six times sweeping over the light spot area 16, to 9.9 kHz, only 30 _/ uA beam current Ia was required (upper curve in FIG. 3).

This example shows that even when using standard, commercially available optical imaging elements with moderate light intensity, the light output with cathodes required for electrophotographic printing in the medium speed range (15 to 30 pages A4 / min) can achieve jet tubes.

A sufficient service life of the phosphor layer of the screen 9 is achieved when the beam over the whole of a DIN A4 page reaching raster line by approximately half the spot diameter is set from about 50 _/ um vertically after each printing operation. After a total offset of approximately 3 mm, the return to the starting line can take place, whereupon the vertical deflection cycle begins again. This gives a screen area (illuminated area 16) of 0.3 × 20 cm = 6 cm ² , which, with the above values, leads to a beam power density of approx. 0.15 to 0.2 W / cm ² . This power density corresponds to a service life of far more than 1000 hours for the cathode ray tube.

Claims (7)

1. A method for the electrophotographic representation of an electrically stored information with a cathode ray tube, the luminescent layer is covered line by line according to the stored information by a cathode ray, and with a photoconductive recording medium, on the photoconductive layer through the activated luminescent layer of the cathode ray tube via an optical system, a mosaic-like latent Charge image is created, which is then transferred to another recording medium, the minimum line frequency with which the cathode beam is deflected corresponds to the quotient of the feed speed of the recording medium and the line spacing, characterized in that each individual raster line separately the same information content of the mosaic-like charge image to be recorded generated by the cathode ray controlled according to the stored information on the screen of the cathode ray tube , transferred to the recording medium by means of an optical imaging system and recorded there that this cathode ray represents the information content of the same raster line several times in succession at a line frequency which is higher than the minimum line frequency, and that the recording medium is moved continuously. 2. The method according to claim 1, characterized in that the light spots generated by the electron beam on the screen of the cathode ray tube in their size correspond to the grid points to be recorded on the recording medium. 3. The method according to claims 1 and 2, characterized in
that the line frequency of the cathode ray tube deflection is increased by a factor of 2 to 10 compared to the minimum line frequency. 4. cathode ray tube for performing the method according to claims 1 to 3, characterized in that the height (H) of the screen (9) is substantially less than its width (L). 5. cathode ray tube according to claim 4, characterized in
that the screen 9 is coated with a highly efficient phosphor. 6. cathode ray tube according to claims 4 and 5, characterized in
that the height of the illuminated dot area (16) corresponds approximately to the size of the raster dots to be recorded on the recording medium (1) and
that only a deflecting system (10) for the horizontal Ab _- deflection of the cathode beam is provided. 7. cathode ray tube according to claims 4 and 5, characterized in
that a vertical deflection system is provided that after each image of a raster line of the same information content deflects the cathode ray by about half a raster line height and
that after several vertical deflections, the deflection reverts to the first raster line.

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