DE3027194A1 - Electrophotographic printer with low output lasers - combines two lasers into writing beam using reflecting optics - Google Patents

Abstract

An electrophotographic printer has two separate low power lasers (2,4) whose beams are combined into a single writing beam to discharge selective parts of a charged web prior to processing with toner powder. The toner image is then transferred to a copy sheet and fixed. The two lasers provide a compact and low cost light source and replace a larger, costly laser. One laser has a continuous output while the other has a modulated output corresponding to the writing data. Correction elements (9,10) are positioned in one light path so that both beams are accurately aligned with the writing point (17).

Description

Electrophotographic writing method and device for

Carrying out the method The invention is based on an electrophotographic Writing method of the type specified in the preamble of claim 1.

To generate a charge image on a photoconductive semiconductor layer, the z. B. can be a selenium drum, a zinc oxide master foil, etc., the latter happens first a known device for electrical charging with a Potential of suitable height. By exposure to a modulated light beam As an information carrier, the electrical surface charge on the photoconductive breaks Semiconductor layer together at the points hit by the radiation. Afterward the semiconductor layer is dusted with a toner in a dusting device, whereby, depending on the charge of the toner, either the exposed or the unexposed areas of the charged semiconductor layer the color particles of the toner by the electric field forces.

This electrophotographic writing process requires a specific one supplied light power, which is supplied in the form of the modulated light signal itself can be. But you need a relatively high light output of the information carrier beam, thus the electrical surface charge as a result of the energy absorption from the radiation on the photoconductive semiconductor layer at the points hit by the radiation collapses, d. H. is made to disappear almost completely. Radiation sources with such a high light output are relatively expensive and have a long service life often very limited, especially when using semiconductor lasers as radiation sources.

For this reason, an alternating high voltage corona discharge device, by reducing the potential of the surface charges on the photoconductive Semiconductor layer is achieved in conjunction with a lower energy modulated Light bundle has been proposed (DE-AS 15 22 568). By an AC corona discharge however, none is obtained over the entire writing surface of a recording medium Even and clean typeface, because of the large scattering effect of the alternating field no targeted effect is possible.

The same effect as with an alternating field is also with a rod-shaped one Light source achievable, which also has a multi-line area over the entire line length covered. But here, too, there is a large scattering effect because of the scattered light and thus an unclean typeface that is uneven in contrast. It remains often also residual charges that are subsequently extinguished by additional light sources, d. H. removed, must be, but on the one hand the desired charge pattern is further weakened and on the other hand, the energy consumption and the temperatures in the entire device are unnecessary raise.

The invention is based on the object of an electrophotographic Writing method and a device for carrying out this method of the im To create the preamble of claim 1 specified type, which the indicated Avoids disadvantages of known methods and creates them in the simplest possible way enables clean, high-contrast characters.

According to the invention, this object is achieved by the characterizing measures of claims 1 and 8 solved.

The inventive use of two light beams whose Effect is added, the supplied light power is depending Beam of light reduced, so that more cost-effective radiation sources with a longer service life can be used, which is essential with regard to the use of semiconductor lasers Meaning is. In addition, by adding the energies of the two is punctiform Light rays can have a targeted effect without a scattering effect, so that according to the invention Writing method of electrostatic contrast, d. H. the surface potential difference between exposed and non-exposed areas, is increased and thus richer in contrast and sharper typefaces can be achieved. The subject matter of the invention also has to have the advantage that due to the intensity modulation of the light rays easy way different shades of gray and thus different contrasts can be achieved between information and background.

Advantageous further developments of the invention are set out in the subclaims specified.

An embodiment of the invention is described below with reference to the The drawing shows: FIG. 1 shows a device for carrying out the electrophotographic Writing method in a diagrammatic representation and FIGS. 2 to 6 according to the invention Writing process with different contrast generated characters.

FIG. 1 shows the path of a light beam 1 from a light source 2 and a light beam 3 from a light source 4 to a common mirror 5, which the light rays 1 and 3 in a direction perpendicular to the axis 6 of the Mirror 5 reflected.

Between the light sources 2 and 4 and the mirror 5 are two common adjustable mlenkspiegel 7 and 8 arranged. In addition, 3 is in the beam path A deflecting mirror 9 is arranged between the light source 4 and the deflecting mirror 7, which is adjustable by adjusting members 10 so that the deflecting mirror 9 by two intersecting axes is adjustable, as will be explained in detail. In The path of the light rays 1 and 3 can also lens systems, not shown be arranged to expand the light beams 1 and 3 and focus.

The light sources 2 and 4 are advantageous as semiconductor laser diodes formed, the light beams 1 and 3 according to the information to be written modulate directly. When using a gas laser, e.g. B. HeNe lasers as a light source 2 or

4 is in the beam path of the light beam 1 and 3 respectively an acousto-optical Arranged modulator 11 and 12, the light beam 1 and 3 according to the to modulated writing and information contained in an electrical signal.

The common mirror 5 oscillates as a constant frequency moving mirror galvanometer 13 formed. Optionally, the light reflection can also be made with the help of other suitable facilities, for example by a rotating mirror driven by a constant speed motor and has a number of reflective side surfaces, which are called regular Quadrangles are formed. The light rays 1 and 3 are from the mirror 5 in reflect the same horizontal plane in which they hit the mirror 5. Both light beams 1 and 3 reach a photosensitive intermediate carrier 14, which is a photoconductive semiconductor layer, e.g. B. of zinc oxide, and on a roller 15 is performed. A motor is functionally connected to the roller 15, to rotate this.

The intermediate carrier can also be used as a drum with a photoconductive Semiconductor layer, z. B. be formed with a selenium coating.

Happened to generate a charge image on the semiconductor layer the intermediate carrier 14 initially a known device for electrical Charging with a potential of a suitable level. After charging, breaks the electrophotographic writing process, the uniform electrostatic surface charge on the photoconductive semiconductor layer by exposure to the light rays 1 and 3 together at the points hit by the radiation, because in the exposed Share the photoconductive semiconductor layer becomes conductive and therefore the charge can drain.

The two focused light rays 1 and 3 extend from theirs Light sources 2 and 4 from converging on the common mirrors 7, 8 and 5 and fall on a common point of impact 16 on the semiconductor layer of the intermediate carrier 14 together and are covered by the oscillating mirror 5 at the same time the recording line 17 moves. Alternatively, the mirrors 7 to 9 can also be of this type be set so that the two light beams 1 and 3 adjacent on the common Recording line 17 impinge on the semiconductor layer of the intermediate carrier 14 and through the mirror 5 directly one behind the other or one above the other over the recording line 17 are moved.

The setting of the light beam shown on the intermediate carrier 14 3 with respect to the light beam l takes place through the adjusting members 10. After loosening a screw 101, the deflection mirror 9 is pivotable about a pin 102, whereby the light beam 3 is set in the horizontal on the intermediate carrier 14. After loosening a nut 103, the deflecting mirror is 9 around an axis 104 rotatable, whereby the light beam 3 is adjustable in the vertical. the both axis lines of the pin 102 and the axis 104 intersect on the surface of the deflection mirror 9. In this way, it is made possible with simple means to Light beam 3 with light beam 1 in a common focal point 16 on the semiconductor layer of the intermediate carrier 14 to overlap or both light beams 1 and 3 on the common recording line 17 adjacent to the semiconductor layer to hit.

For simultaneous setting of both light beams 1 and 3 on the The semiconductor layer of the intermediate carrier 14 is the light sources 2 and 4, the deflection means 9, 10 and the adjustable deflection mirrors 7 and 8 on a common carrier 18 arranged, after loosening a locking screw 19 by two horizontally arranged Pin 20 is pivotable. The pins 20 are fastened in a receiving plate 21, by means of three elongated holes 22 on two pins 23 or a locking screw 24 of a base plate 25 is pivotable about a pivot bearing, the axis of which with the vertically arranged axis 6 of the mirror 5 coincides. The axis lines of the tenons 20 and the axis 6 intersect on the surface of the mirror 5. In this way, becomes a common adjustment of the two light beams impinging on the intermediate layer 14 1 and 3 vertically and horizontally.

According to a first embodiment, both light beams 1 and 3 corresponding to the one to be written and contained in an electrical signal Information is modulated so that at a certain point on the intermediate carrier 14 both light beams 1 and 3 are switched on or off. The one modulated light beam 1 causes a potential reduction, i.e. H. partial removal of the surface charges, at the exposed areas on the photoconductive semiconductor layer of the intermediate carrier 14. The another modulated light beam 3 causes to the from Radiation hit points a further decrease in potential and thereby drafts a latent image on the recording line 17 of the photosensitive intermediate carrier 14 according to the information transmitted to the modulators 11 and 12 or laser diodes 2 and 4.

By adding the energy of the two point-like light rays 1 and 3, the supplied light power per light beam is reduced and a targeted one Effect achieved without scattering effect, so that the electrostatic contrast, i. H. the Surface potential difference between the exposed and the unexposed Areas, is increased and thus high-contrast and sharp typefaces can be achieved are. The latent charge image on the semiconductor layer of the intermediate carrier 14 is developed by means of toner particles according to any known method, whereby z. B. only the unexposed areas of the charged semiconductor layer in are able to hold the color particles of the toner by the electric field forces. Alternatively, a positively charged toner can be applied to the erased areas of the Intermediate carrier 14 has a sufficiently high potential for a jump to the semiconductor layer have so that only the exposed areas of the charged semiconductor layer contain the color particles of the toner by the electric field forces. The developed image will finally transferred to a record carrier by some known method. The motor for rotating the roller 15 is in some known manner with the motor 13 for moving the mirror 5 and the modulators 11 and 12 are synchronized. on this way you get black writing on a white background, as in figure 2 is shown. By reverse modulation of the two light beams 1 and 3 can with a so-called no information, i. H. with a white font black background, as shown in Figure 3.

According to a second embodiment, only the one light beam 1 or 3 modulates according to the information to be written, while the other Light beam 3 or 1 remains unmodulated and shines continuously. By the sole There is only one effect of the unmodulated, continuously radiating light beam partial potential reduction of the electrical surface charge on the photoconductive Semiconductor layer of the intermediate carrier 14 instead, so that at these points a smaller Amount of toner particles retained and thus gray tones are generated. Through the The additive effect of both light rays 1 and 3 completely breaks the surface charge or almost completely together, so that at the points hit by the radiation the surface charge can flow away via the semiconductor layer and no toner particles be held. In this way, with gray letters on a white background, according to Figure 4, or written with white letters on a gray background, as shown in FIG.

In the embodiments described so far, it was assumed that both light sources 2 and 4 radiate with the same intensity. Both can Light sources 2 and 4, however, also shine with different intensities. By this intensity modulation of one light beam or both light beams can different shades of gray can be achieved in a simple manner. Radiates z. B. one light source with lower and the other light source with normal energy, so, due to the additive effect of the two light rays, it is not complete Potential lowering of the electrical surface charge and thus a smaller amounts of toner particles are retained and gray tones are produced. By The electrostatic surface charges remain corresponding to modulation of both light beams completely preserved, so that - as Figure 6 shows - with black writing on gray Background can be written.

According to the electrophotographic writing method of the present invention and with a device for carrying out the writing method described it is thus possible in a simple manner either by modulating both light beams or by modulating one beam of light and continuous radiation of the other Light beam and / or by an intensity modulation of one or both light sources to achieve different contrasts, as shown in Figures 2 to 6, to z. B.

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Claims (14)

Claims: 1. Electrophotographic writing process in which uniform electrostatic surface charges on a photoconductive semiconductor layer partially by exposure by means of a modulated, deflected light beam are removed and then that generated thereby on the semiconductor layer latent charge image is developed by means of a toner to produce visible characters to get that the removal of the Surface charges at the exposed areas on the photoconductive semiconductor layer (14) is carried out by adding the energy of two light rays (1, 3). 2. The method according to claim 1> d a d u r c h g e k e n n -z e i c h n e t that the light beams (1, 3) are generated by two separate laser sources (2, 4) generated and deflected so that they are on a common recording line (17) impinge on the semiconductor layer (14). 3. The method according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the light beams (1, 3) generated by two separate laser sources (2, 4) and are deflected in such a way that they arrive at a common point of impact (16) the semiconductor layer (14) coincide. 4. The method according to any one of claims 1 to 3, d a d u r c h g e k e n n z e t c h n e t that both light beams (1, 3) correspond to the one to be written Information are modulated. 5. The method according to any one of claims 1 to 3, d-a d u r c h g e k It is indicated that the one light beam (1 or 3) corresponds to the to writing information is modulated and the other unmodulated light beam (3rd or 1) continuously radiates. 6. The method according to any one of claims 1 to 5, d a d u r c h g e k It is noted that the two light sources (2, 4) with different Radiate intensity. 7. The method according to any one of claims 1 to 6, d a d u r c h g e k It is indicated that the focused light rays (1, 3) of the two light sources (2, 4) brought to overlap in this way via a common movable mirror (5) be that they are simultaneously moved covering the recording line (17). 8. Device for performing the method according to one of the claims 1 to 7, d u r c h g e k e n n -z e i c h n e t that two light sources (2, 4) are provided, the separate beams (1, 3) of which can be deflected in this way. that they can be brought to cover on the semiconductor layer (14). 9. Apparatus according to claim 8, d a d u r c h g e k e n n -z e i c h n e t that in the beam path of one light beam (3) adjustable deflection means (9, 10) are arranged through which the light beam (3) with the other light beam (1) in a common focal point on the semiconductor layer (14) for overlap can be brought. 10. The device according to claim 9, d a d u r c h g e k e n n -z e i c h n e t that for setting both at the same time Rays of light (1, 3) on the semiconductor layer (14) the light sources (2, 4) and the deflection means (9, 10) are arranged on a common carrier (18) which is controlled by adjusting members (19 to 24) is adjustable about two intersecting axes (6, 20). 11. Device according to one of claims 8 to 10, d a -d u r c h it is noted that the light sources (2, 4) are designed as laser diodes are. 12. Device according to one of claims 8 to 11, d a -d u r c h it is not indicated that in the ray paths of the two light rays (1, 3) each an acousto-optical modulator (11, 12) is arranged through the light rays (1, 3) corresponding to that contained in an electrical signal Information can be modulated. 13. Device according to one of claims 8 to 11, d a -d u r c h it is not noted that in the beam path of a gas laser generated light beam (1 or 3) an acousto-optical modulator (11 or 12) is arranged through which the light beam (1 or 3) corresponding to that in an electrical The information contained in the signal can be modulated, and that the other light beam (3 or 1) remains unmodulated and radiates continuously. 14. Device according to one of claims 8 to 13, d a -d u r c h it is not indicated that in the ray paths of the two light rays (1, 3) a common rotatable multi-surface mirror or an oscillating mirror (5) is provided through which the focused light beams (1, 3) of the two separate Light sources (2, 4) can be moved simultaneously covering the recording line (17) are.