DE102007033238A1 - Method for generating printed images, involves generating loading image of printed image on photo conductor by illumination of photo conductor - Google Patents

Abstract

The method involves generating a loading image of a printed image on a photo conductor (1) by illumination of the photo conductor. The loading image is dyed with charged toner by tribo jumps (6,9) arranged in developer stations (5,8) and lying at a pre-voltage or bias voltage. A photo conductor area is not reloaded below the toner image by a transfer unit (12).

Description

The development of on a charge image carrier, z. As a photoconductor drum, applied charge images of images to be printed in an electrophotographic printing or copying device according to the toner jump principle is known (see, for example PAT 1991-366857; US 4,868,600 ). In this principle, a toner cloud of toner particles is generated in the space between the developer roller (jump roller) and charge image carrier (hereinafter called development area) by applying an AC voltage and / or DC voltage from the toner particles according to the charge images on the charge image carrier and thus color it. Multi-color printing requires the charge images to be sequentially colored with toner particles of different colors. For this purpose, a corresponding number of developer stations can be arranged along the charge image carrier ( US 5,828,933 ; GB 2 343 144 A ). There is a risk that when the toner cloud is generated in the development area according to the toner jump principle, toner particles also impinge on the charge image carrier and at least partially replace a toner layer of a different color previously applied by a preceding developer station. However, this falsifies the previously printed color image and contaminates the developer mixture of this developer station.

The The problem underlying the invention is a method indicate the toner images already present on the charge image carrier, z. B. at serial pressure, are not affected and subsequent Developer stations are not contaminated.

This Problem is solved according to the features of the claim 1 solved.

If at one along a circumferential and at an initial potential preloaded photoconductor are arranged on the same side printing units, each one character generator and one after the tribo-jump principle have working developer station, through each of which a charge image of a Print image is generated on the photoconductor and this charge image by a bias voltage arranged in the developer station (Biasspannung) Jumping roller with charged toner to the toner image is colored, there is a risk that one through a first printing unit generated toner image in the subsequent printing unit is damaged by the toner of the first toner image Toner of the subsequent printing unit is removed and in the Developer station of the subsequent printing unit passes.

in the The following will explain the solution of the Problems as an example of a printing device with two in series arranged printing units assumed. The first one generates Print unit, a first charge image, the first toner image of a first print image is developed and the subsequent second printing unit a second charge image corresponding to the second toner image of a second print image is developed. However, the solution is not up Restricting printing devices with two printing units, it can also be transferred to printing devices with more than two printing units become.

The Danger of carryover of toner from a first toner image in the developer station of a subsequent printing unit can thereby can be reduced that by the first printing unit with toner developed charge image (first toner image) after leaving this Pressure unit and before reaching the next second Druckein unit together with the photoconductor by a Umladeeinheit to a Umladepotential is transferred, which is the transition of toner of the first toner image in the developer station of the second printing unit prevents. Thereby is achieved that the toner of the first toner image is not in the Developer station of the subsequent printing unit passes.

further developments The invention will become apparent from the dependent claims.

In a first embodiment of the invention, the Umladepotential correspond to the initial potential of the photoconductor.

A Further improvement can be achieved if the transhipment potential in terms of amount greater than that Initial potential of the photoconductor is selected.

If the photoconductor with the first toner image before transhipment through a first intermediate exposure unit is discharged again and then by the recharging unit is charged to a Umladepotential, the amount is greater than the initial potential, the Liability of the first toner on the photoconductor significantly increased and moving that toner to the developer station of the subsequent ones Printing unit largely prevented.

This Effect is further enhanced when passing through the first intermediate exposure unit the photoconductor is discharged into saturation, so that after the charge, the potential of the toner image in terms of amount is greater than the Umladepotential the photoconductor.

The development of the second charge image by the subsequent printing unit can be improved by that before reaching the next Printing unit after reloading through a second intermediate exposure unit of Fotolei ter is discharged to a potential corresponding to the initial potential of the photoconductor.

This can be specifically achieved when the potential of the photoconductor after the second intermediate exposure via a charge sensor is measured and the intermediate exposure regulated by the measurement signal becomes.

• – Dieses Ziel kann in einer ersten Lösung erreicht werden, wenn nach der Umladung des Fotoleiters durch die Umladeeinheit der Zeichengenerator der nachfolgenden zweiten Druckeinheit in einem Bildbereich, in dem das erste und das zweite Druckbild erzeugt werden soll, den Bildbereich außerhalb des ersten Druckbildes mit dem Inversbild des ersten Druckbildes belichtet und zudem in diesem Bildbereich das Ladungsbild des zweiten Druckbildes auf dem Fotoleiter erzeugt. Hier ist es besonders vorteilhaft, wenn durch den Zeichengenerator der zweiten Druckeinheit nur an dem Randbereich des zweiten Druckbildes eine Belichtung mit dem Inversbild des ersten Druckbildes erfolgt. Die Belichtung des Fotoleiters mit dem Inversbild des ersten Druckbildes kann mit Hilfe eines nach dem Zeichengenerator angeordneten Ladungssensors geregelt eingestellt werden.
• – Dieses Ziel kann in einer zweiten Lösung erreicht werden, wenn als Zeichengenerator ein LED-Zeichengenerator verwendet wird, mit dem einstellbar der Randbereich des zweiten Druckbildes durch punktweise Belichtung (Rand-PEL-Belichtung) auf ein optimales Ladungspotential für die Entwicklung des zweiten Ladungsbildes eingestellt wird, z. B. auf Anfangspotential umgeladen wird. Bei die ser Lösung kann die Breite des Randbereiches durch die punktweise Belichtung durch den Zeichengenerator eingestellt werden. Zudem kann die Intensität der Umladung im Randbereich durch die Einstellung der Intensität der Belichtung der LED's des Zeichengenerators festgelegt werden. Dann ist die Erzeugung des zweiten Druckbildes unabhängig vom ersten Druckbild, zudem können Druckbilder mit feinen Zeichen und Rastern besser erzeugt werden.

An optimum result is achieved when the character generator of the following printing unit is controlled so that it sets the area on the photoconductor in which the second charge image is to be formed to a charge potential that is optimal for generating the charge image. This can be z. B. be the initial potential.

• This goal can be achieved in a first solution, if after the reloading of the photoconductor by the transfer unit, the character generator of the subsequent second printing unit in an image area in which the first and the second print image is to be generated, the image area outside the first print image with the Inverse image of the first printed image exposed and also generated in this image area, the charge image of the second print image on the photoconductor. Here, it is particularly advantageous if the character generator of the second printing unit is only exposed to the inverse image of the first printed image at the edge region of the second printed image. The exposure of the photoconductor to the inverse image of the first print image can be regulated by means of a charge sensor arranged after the character generator.
• - This goal can be achieved in a second solution when an LED character generator is used as a character generator, set with the adjustable edge of the second print image by pointwise exposure (edge-PEL exposure) to an optimal charge potential for the development of the second charge image is, for. B. is reloaded to initial potential. In the water solution, the width of the edge area can be adjusted by the pointwise exposure by the character generator. In addition, the intensity of the transhipment in the peripheral area can be determined by the adjustment of the intensity of the exposure of the LEDs of the character generator. Then, the generation of the second print image is independent of the first print image, moreover, printed images with fine characters and grids can be better produced.

Based of embodiments shown in the figures are, the invention will be further explained.

It demonstrate

1 an electrophotographic printing device,

2 a timing diagram which illustrates, in principle, plotted versus time the electrical potential on a photoconductor in the production of two serial printed images by two printing units without the use of the invention;

3 a pulse diagram accordingly 2 representing the potential on the photoconductor when, between the generation of the two images by the two printing units, the photoconductor has been reloaded;

4 a pulse diagram accordingly 2 representing the potential on the photoconductor when the photoconductor is overcharged during transhipment;

5 a pulse diagram accordingly 2 representing the potential on the photoconductor if the photoconductor has been exposed again before being transposed;

6 a pulse diagram accordingly 2 representing the potential on the photoconductor if, after the transfer, the photoconductor has once again been subjected to intermediate exposure;

7 a pulse diagram accordingly 2 representing the potential on the photoconductor when the character generator of the second printing unit is controlled by a charge sensor;

8th a first print image after inverse exposure with the first print image;

9 the first and second printed image with inverse exposure of the second printed image only in its edge region;

10 a pulse diagram accordingly 2 representing the potential on the photoconductor when producing more than two printed images in series on the photoconductor of the invention; and

11 a control circuit for controlling the character generator of the second printing unit.

Out 1 results in the basic structure of an electrophotographic printing device. To a photoconductor 1 , in 1 a photoconductor belt, in the exemplary embodiment two Druckseininheiten DE1 and DE2 are arranged, with which toned with toner charge images on the photoconductor 1 can be generated, which are arranged in series with each other. The photoconductor 1 becomes in the direction of the arrow 2 emotional. Before the photoconductor 1 reaches the printing unit DE1, it is cleaned in a cleaning unit RE, which lies behind a transfer printing station US, in which the toner images are transferred to a printing substrate AT.

Each printing unit DE1, DE2 has a character generator 4 . 7 and a developer station 5 . 8th on. As a character generator 4 . 7 can z. B. an LED character generator can be used, the photoconductor 1 discharges according to the images to be printed by exposure and thus generates charge images of the printed images, which are developed in a developer station. As a developer station 5 . 8th may be a tribo-jump process developer station 5 . 8th whose mode of operation is known and which will be explained again below:
From a developer mixture of carrier and toner is the developer of a jump roller after mixing by a magnetic roller 6 . 9 supplied as a developer roller, which takes over from the magnetic roller charged toner. The toner becomes one between the jump roller 6 . 9 and the photoconductor 1 fed developer gap formed there forms a toner cloud, from the toner to the photoconductor 1 arrives to color the charge images there. To transfer the toner from the toner cloud to the photoconductor 1 to assist is to the Jumpwalze 6 . 9 a bias voltage, a bias voltage, applied, the electric field forces between Jumpwalze 6 . 9 and the charge images on the photoconductor 1 due to which charged toner is moved toward the charge images.

Operational ( 2 ) becomes the photoconductor 1 first through the charger 3 charged to an initial potential U _a . Then the photoconductor is running 1 in the first printing unit DE1. There is the charged photoconductor 1 in accordance with the images to be printed by the first printing unit DE1 (first printed images DB1) from the character generator 4 exposed, so that first charge images LB1 of the first printed images DB1 to be printed on the photoconductor 1 be generated. These charge images LB1 are in the first developer station 5 the printing unit DE1 with toner to first toner images TB1 dyed. Between the character generator 4 and the developer station 5 can be a charge sensor 10 be provided by which the charge on the photoconductor 1 is measured and dependent on the exposure by the character generator 4 and the charging by the charger 3 is regulated.

The second printing unit DE2 becomes the photoconductor 1 through the second character generator 7 exposed to a second print image DB2 to be printed and the photo guide 1 unloaded accordingly. The charge images LB2 generated by the second printing unit DE2 are adjacent to the first toner images TB1. The second charge images LB2 are passed through the second developer station 8th developed to second toner images TB2.

The two by the printing units DE1 and DE2 on the photoconductor 1 generated toner images TB1, TB2 are in a transfer station US in a known manner to a substrate AT, z. As paper, and printed there fixed in a known manner.

Along the photoconductor 1 Further units can be arranged to improve the quality of the print images DB. Between the printing units DE1 and DE2, a recharging unit 12 be provided to the photoconductor 1 recharge behind the pressure unit DE1. Furthermore, between the first and second printing units DE1 and DE2, a first intermediate exposure unit 13 be used to the photoconductor 1 to be able to unload. This intermediate exposure unit 13 can in front of the recharging unit 12 lie. Finally, between character generator 7 and developer station 8th the second printing unit DE2 another charge sensor 11 are used by the measuring signal, the exposure by the second character generator 7 and the transhipment through the transhipment unit 12 can be regulated. Finally, between the recharging unit 12 and the second printing unit DE2, a second intermediate exposure unit 14 be arranged to the photoconductor 1 depending on the application to be able to expose again.

Based on 2 to 10 the function of the printing device is further explained. The 2 to 10 show pulse diagrams in which the course of the electric potential on the photoconductor 1 in the production of printed images DB by the printing units DE1 and DE2 is applied and this with different use of the units th along the photoconductor 1 , It is assumed in the embodiments that the toner is negatively charged and the potentials on the photoconductor 1 are also negative. However, the invention is also positive for positively charged toner and positive potentials on the photoconductor 1 used. In the 2 to 9 it is only shown how two print images DB of different colors are produced in succession and side by side by the printing units DE1 and DE2. 10 shows the case that by another pressure unit (in 1 not shown) a third printed image on the photoconductor 1 is produced. Both 2 to 10 are above the timing diagrams, the functional units of the printing device specified, the photoconductor 1 influence in the manner shown.

2 shows the initial situation when toner images TB of print images DB on the photoconductor are sequentially serially produced by the two printing units DE1 and DE2 1 be produced, the invention is not used. With 2 should the pro Bleme be shown that occur in operation without invention. Through the charger 3 becomes the photoconductor 1 initially charged to an initial potential U _a , z. B. to about -500 V. Subsequently, the photoconductor 1 through the character generator 4 discharged according to the image to be printed, z. B. to a discharge potential U _e1 of z. B. about -40 V. The generated charge image LB1 is in the next step in the developer station 5 colored with toner T1 of a first color, this process is assisted by the bias voltage at the jump roller 6 z. B. is about -300 V and thereby the movement of the negatively charged toner T1 is supported to the charge image LB1. This results in the first toner image TB1, which is represented symbolically by two toner particles T1. The toner image TB1 has a more negative potential U _t1 compared to U _e1 . The photoconductor 1 is moved on to the printing unit DE2. In the printing unit DE2 becomes the photoconductor 1 adjacent to the toner image TB1 by the character generator 7 exposed according to the image to be printed and thereby discharged again to the discharge potential U _e1 to the charge image LB2. Subsequently, the charge image LB2 in the developer station 8th toned toner T2 of a different color to a toner image TB2.

• – Da das Tonerbild TB1 auch durch die Entwicklerstation 8 läuft, besteht die Gefahr, dass durch die dort im Entwicklerspalt bestehende Tonerwolke aus Toner T2 Toner T1 aus dem Tonerbild TB1 gelöst wird, dieser in die Entwicklerstation 8 gelangt und dort das Entwicklergemisch verunreinigt.
• – Durch das Herauslösen von Toner T1 aus dem Tonerbild TB1 wird dieses verschlechtert oder ganz zerstört.
• – Weiterhin besteht die Gefahr, dass dadurch bei dem ersten Tonerbild TB1 und damit dem ersten Druckbild eine verstärkte Hintergrundbildung auftritt und dies ebenfalls im nicht umgeladenen Bereich des Fotoleiters 1.

If the generation of the toner images TB corresponding 2 is performed, some problems occur:

• - Since the toner image TB1 also by the developer station 8th runs, there is a risk that is solved by the there in the developer gap toner cloud of toner T2 toner T1 from the toner image TB1, this in the developer station 8th and there contaminated the developer mixture.
• - The dissolution of toner T1 from the toner image TB1 this is deteriorated or completely destroyed.
• - Furthermore, there is a risk that in the first toner image TB1 and thus the first printed image increased background formation occurs and this also in the untransferred region of the photoconductor 1 ,

These relationships are in 2 and the following figures indicated that the toner image TB1 toner T1 is missing and the toner image TB2 toner T1 is located.

The disadvantages after 2 are avoided in the invention by various measures, which are described below and which are used according to the desired quality of the printed images.

A first measure may be related to 3 be explained. Here, after formation of the first toner image TB1, the photoconductor becomes 1 along with the toner image TB1 through the transfer unit 12 charged again to a Umladepotential U _h1 , the z. B. the initial potential U _a , and also the toner images TB1 are raised accordingly in potential to _Ute . Thus, the potential of the toner image TB1 is more negative compared to the bias voltage of the jump roller 9 , Due to the higher negative toner potential of toner image TB1 the adhesion to the photoconductor becomes on the one hand 1 On the other hand, the repulsive forces of the toner T1 to the toner T2 become larger. The result is that less toner T1 from the toner image TB1 in the developer station 8th is replaced.

Further improvement occurs when appropriate 4 through the transhipment unit 12 the photoconductor 1 is charged to a Umladepotential U _h2 and the first toner image TB1 to the potential U _t3 , which is more negative than the initial potential U _a (overcharge of the toner image TB1). As a result, a more negative charge of the toner image TB1 is achieved, with the result that its adhesion to the photoconductor 1 is increased. Further, a larger potential difference of the first toner image TB1 becomes the toner T2 in the second developer station 8th (higher repulsive effect) and thus prevents transhipment of the toner T1 of the first toner image TB1. With the transhipment unit 12 can the photoconductor 1 z. B. on U _h2 about -870 V charged.

The solution after 4 has the disadvantage that the photoconductor 1 is overloaded and the development of the second toner image TB2 and thus the second print image DB2 is deteriorated, especially when playing fine characters. To prevent this, can be done accordingly 5 be proceeded. Here is the photoconductor 1 before its reloading a first intermediate exposure by the intermediate exposure unit 13 exposed and thereby in saturation on z. B. U _e2 ≈ -20 V further discharged, the potential of the toner image TB1 can be z. B. be discharged to U _t4 ≈ _100V . If now the photoconductor 1 through the transhipment unit 12 is recharged, the toner image TB1 is charged negative compared to the photoconductor 1 ; z. B. U _h3 ≈ -750 V and U _t5 ≈ -800 V. This will overload the photoconductor 1 reduced. The consequence is also that the return transfer of toner T1 of the first toner image TB1 in the developer station 8th is prevented.

Further improvement is achieved if appropriate 6 the potential of the photoconductor 1 is further reduced while the potential of the first toner image TB1 is not changed. This can be achieved by using the photoconductor 1 a second intermediate exposure by a second intermediate exposure unit 14 is exposed and discharged to a Umladepotential U _h4 , which corresponds to the initial potential U _a . In order to reset the initial potential U _a , can via a charge sensor 11 the potential on the photoconductor 1 and the second intermediate exposure unit 14 be regulated so that the photoconductor 1 the initial potential U _a occupies. Thus, the retransmission of toner T1 of the first toner image TB1 into the developer station becomes 8th prevents and optimal charge potential on the photoconductor 1 provided for the development of the second toner image TB2. A disadvantage of this solution is when the toner T1 of the first charge image LB1 transmits light permeable to the light wavelength of the exposure of the second intermediate exposure unit 14 is because then the toner overload of the first toner image TB1 is also lost.

• – Dieses Ziel wird z. B. dadurch erreicht, dass der Zeichengenerator 7 in einem Bildbereich BB, in dem das erste und zweite Tonerbild TB1, TB2 erzeugt wird, den Bereich außerhalb des ersten Tonerbildes TB1 mit dem inversen Bild des ersten Tonerbildes TB1 belichtet. Anschließend wird das zweite Tonerbild TB2, wie bei 6 beschrieben, erzeugt und dazu der Fotoleiter 1 auf ca. 40 V entladen. Diese inverse Belichtung ergibt sich prinzipiell aus 8, bei der ein Bildbereich BB um das erste Druckbild DB1 und zweite Druckbild DB2 gezeigt ist, bei dem das erste Druckbild DB1 einfarbig dargestellt ist, während der übrige Bereich um das erste Druckbild DB1 gestrichelt die Belichtung mit dem inversen Ladungsbild LB1 darstellt. Die Belichtung des Bereiches um das erste Druckbild DB1 wird mit dem zweiten Zeichengenerator 7 durchgeführt. In dem gestrichelten Bildbereich BB kann das Ladungspotential U_h6 eingestellt werden und dann durch den zweiten Zeichengenerator 7 das Ladungsbild LB2 erzeugt werden.
• – Dieses Ziel kann auch dadurch erreicht werden, dass nur in einem Randbereich RB des zweiten Ladungsbildes LB2 die Belichtung mit dem inversen ersten Ladungsbild LB1 durchgeführt wird (9). In 9 ist ein Bildbereich BB gezeigt, bei dem das erste Druckbild DB1 und das zweite Druckbild DB2 nebeneinander liegen und nur der Randbereich RB um das Druckbild DB2 durch den Zeichengenerator 7 belichtet worden ist.
• – Weiterhin kann dieses Ziel erreicht werden, wenn bei Verwendung eines LED-Zeichengenerators als Zeichengenerator 7 der Randbereich RB durch diesen punktweise belichtet wird. Jeder Bildpunkt (pixel), der von einer LED des LED-Zeichengenerators 7 erzeugt wird, entlädt punktweise den Fotoleiter 1 zu einem PEL (printed element) auf dem Fotoleiter 1, der mit Toner eingefärbt den Druckpunkt (dot) bildet. Die LED's des LED-Zeichengenerators 7 können auf bekannte Weise so angesteuert werden, dass sie wahlweise einzelne PEL's durch Belichtung im Randbereich RB erzeugen und damit den Randbereich RB einstellbar entladen. Durch Auswahl der LED's kann die Breite des Randbereiches RB eingestellt werden, durch Einstellung der Intensität der Belichtung das Ausmaß der Entladung. Dieses Verfahren hat den Vorteil, dass kein Einfluss des ersten Druckbildes DB1 auf das folgende Druckbild DB2 besteht. Zudem kann der Fotoleiter 1 gezielt auf ein Ladungspotential U_h6 entladen werden, das eine optimale Entwicklung der Ladungsbilder LB2 ermöglicht. Z. B. kann das Ladungspotential U_h6 auf das Anfangspotential U_a eingestellt werden. Mit diesem Verfahren kann dadurch eine Tonerverschleppung von Toner T1 des ersten Tonerbildes TB1 in die zweite Entwicklerstation 8 vermieden werden.

A solution for this case can 7 be removed. Here is dispensed with the second intermediate exposure. Instead, the second character generator becomes 7 regulated so that it for the generation of the second toner image TB2 the photoconductor 1 on the charge potential U _h6 places z. B. at initial potential U _a .

• - This goal is z. B. achieved in that the character generator 7 in an image area BB where the first and second toner images TB1, TB2 are formed, the area outside the first toner image TB1 is exposed to the inverse image of the first toner image TB1. Subsequently, the second toner image TB2 becomes as in 6 described, generated and to the photoconductor 1 discharged to about 40V. This inverse exposure results in principle 8th in which an image area BB around the first print image DB1 and second print image DB2 is shown, in which the first print image DB1 is shown in monochrome, while the remaining area around the first print image DB1 represents the exposure to the inverse charge image LB1 in broken lines. The exposure of the area around the first print image DB1 is performed with the second character generator 7 carried out. In the dashed image area BB, the charge potential U _h6 can be set and then by the second character generator 7 the charge image LB2 can be generated.
• This objective can also be achieved by carrying out the exposure with the inverse first charge image LB1 only in an edge region RB of the second charge image LB2 ( 9 ). In 9 an image area BB is shown in which the first print image DB1 and the second print image DB2 side by side and only the edge area RB to the print image DB2 by the character generator 7 has been exposed.
• - Furthermore, this goal can be achieved when using an LED character generator as a character generator 7 the edge region RB is exposed by this point by point. Each pixel (pixel) generated by an LED of the LED character generator 7 is generated, discharges point by point the photoconductor 1 to a PEL (printed element) on the photoconductor 1 , which forms the pressure point (dot) colored with toner. The LEDs of the LED character generator 7 can be controlled in a known manner so that they selectively generate individual PELs by exposure in the edge region RB and thus discharges the edge region RB adjustable. By selecting the LEDs, the width of the peripheral area RB can be adjusted, by adjusting the intensity of the exposure, the amount of discharge. This method has the advantage that there is no influence of the first print image DB1 on the following print image DB2. In addition, the photoconductor 1 are selectively discharged to a charge potential U _h6 , which allows optimal development of the charge images LB2. For example, the charge potential U _{h6 can be set} to the initial potential U _a . With this method, a toner entrainment of toner T1 of the first toner image TB1 into the second developer station can thereby be achieved 8th be avoided.

The method according to the invention thus makes it possible to deliberately avoid the disadvantages caused by the fact that the first toner image TB1 passes through the second developer station 8th running. An optimal solution is achieved when the toner image TB1 is overloaded and thus higher adhesive forces to the photoconductor 1 and at the same time have a higher repelling effect on the toner T2 in the second developer station 8th used is being developed. Via a charge sensor 11 can be the character generator 7 regulated to be operated so that the photoconductor 1 to an optimal development potential, z. B. the initial potential is charged.

Typical potentials as an example of the method according to 7 :

• Charge (3): U _a ≈ -500 V Range: (-400 V → -600 V) Exposure (4/7): U _e1 ≈ -40 V Range (-10 V → -100 V) Development (5/8 ): Jump gap ≈ 180 μm range (100 μm → 300 μm)

• 1. Intermediate (13): U _e2 ≈ -20V range (-10 V → -100 V) Concrete area: Depending on the light transmittance of the toner with respect to the wavelength of (13) Reloading (12): U _h5 ≈ -700 V range (-650 V) → -950 V) U _t6 ≈ -750V range (-700 V → -1000 V)
• 2. Intermediate (7): U _h6 -500 V range (-400 → V -600) U _{t7 (translucent)} ≈ -500 V range (-1000 V → -600 V) U _{t7 (translucent)} ≈ -750 V range (-700 V → -1000 V) Inverse: U _h4 ≈ -500 V Range (-400 V → -600).

areas with toner T1 from the 1st print image DB1 are by inverse exposure not impaired.

10 shows the timing diagram of an example in which three printing units along the photoconductor 1 are arranged. The first area corresponds to the course of the 7 (up to the dashed vertical line), then the potential profile is displayed when the third pressure unit (in 1 not shown) a toner image TB3 for a third printed image on the photoconductor 1 generated. First, by an intermediate exposure unit 15 the photoconductor 1 unloaded, followed by a recharging unit 16 a transhipment comparable to that of 7 (transfer unit 12 ). In the following steps becomes the photoconductor 1 by a character generator 17 discharged according to the third printed image to a charge image LB3 and this developed in a developer station of the third printing unit to the toner image TB3. The process and the potential conditions correspond to those of 7 ; it is referred to. Subsequently, printed images lying in series on the same principle can be produced by further printing units.

Out 11 results in a basic circuit of a control circuit z. For example, for the character generator 7 , The charge of the photoconductor 1 is through a charge sensor 11 measured. The measurement signal is compared in a comparison circuit VG with a discharge target value SW. The resulting control difference RD is a discharge controller RG, z. B. a PI controller, supplied to the character generator 7 so that it regulates the desired potential (eg according to 7 ) on the photoconductor 1 established.

The invention has been explained with an embodiment in which the toner is negatively charged and accordingly the potentials on the photoconductor are negative. Of course, the invention can also be used in one embodiment with positively charged toner. In the claims, therefore, the potentials on the photoconductor 1 and indicated on the toner images TB in terms of amount.

DE1

printing unit

DE2

printing unit

RE

cleaning unit

US

transfer station

AT

substrate

DB

print image

LD

charge image

TB

toner image

BB

image area

RB

border area a printed image

T

toner

1

photoconductor

2

Transport direction of the photoconductor 1

3

Charger

4

character generator

5

developer station

6

jump roller

7

character generator

8th

developer station

9

jump roller

10

charge sensor

11

charge sensor

12

transfer unit

13

Between the exposure unit

14

Between the exposure unit

15

Between the exposure unit

16

transfer unit

17

character generator

18

development station

VG

comparison circuit

RG

regulator

RD

Control difference

SW

Discharge setpoint

U _a

initial potential of the photoconductor

U _e

discharge potential of the photoconductor

U _t

toner potential

U _h

Umladepotential of the toner image

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - US 4868600 [0001]
• US 5828933 [0001]
• GB 2343144 A [0001]

Claims (24)

A method for generating juxtaposed on a printing material printed images (DB) (by means of an electrophotographic printing device, in which pre-loaded along a circumferential and an initial potential (U _a) the photoconductor 1 ) are arranged on the same side printing units (DE1, DE2) each having a character generator ( 4 . 7 ) and a tribo-jump principle developer station ( 5 . 8th ), wherein at each printing unit (DE1, DE2) by the character generator ( 4 . 7 ) by exposure of the photoconductor ( 1 ) a charge image (LB) of a printed image (DB) on the photoconductor ( 1 ) and this charge image (LB) by a in the developer station ( 5 . 8th ) arranged at a bias voltage (bias voltage) Jump roller ( 6 . 9 ) is dyed with charged toner (T), in which the charge image developed by a printing unit (DE) with toner (T) to the toner image (TB) after leaving this printing unit and before reaching the next printing unit (DE) together with the photoconductor ( 1 ) with a first transhipment unit ( 12 . 16 ) is charged to a Umladepotential (U _h ), the amount is greater than the tension of the Jumpwalzen ( 6 . 9 ). Method according to Claim 1, in which the charge-reversal potential (U _h1 ) corresponds to the initial potential (U _a ) of the photoconductor ( 1 ) corresponds. Method according to Claim 1, in which the charge-reversal potential (U _h2 ) is greater in magnitude than the initial potential (U _a ) of the photoconductor ( 1 ) is selected. Method according to Claim 3, in which, with an initial potential (U _a ) of 500 V in absolute value, the charge-reversal potential (U _h2 ) is chosen to be 700 V to 900 V in absolute terms. Method according to Claim 4, in which the photoconductor ( 1 ) with the toner image (TB1) before the second charging through an intermediate exposure unit ( 13 ) is discharged further and then by the Umladeladeeinheit ( 12 ) is charged to a Umladepotential (U _h3 ), which is greater in magnitude than the initial potential (U _a ). Method according to Claim 5, in which the first intermediate exposure unit ( 13 ) the photoconductor ( 1 ) is discharged into the saturation (U _e2 ), so that after the charge, the potential (U _t5 ) of the toner image (TB1) in terms of amount is greater than the Umladepotential (U _h3 ) of the photoconductor ( 1 ). Method according to one of claims 5 or 6, wherein before reaching the next printing unit (DE2) after the transfer by a second intermediate exposure unit ( 14 ) the photoconductor ( 1 ) is discharged to a potential (U _h4 ), the initial potential (U _a ) of the photoconductor ( 1 ) corresponds. Method according to Claim 7, in which the potential of the photoconductor ( 1 ) after the second intermediate exposure via a charge sensor ( 10 ) is measured and the intermediate exposure is controlled by the measurement signal. Method according to Claim 5 or 6, in which the character generator ( 7 ) of the subsequent printing unit (DE2) is regulated in such a way that, for the production of the toner image (TB2), it causes the photoconductor ( 1 ) in a region in which the toner image (TB2) is formed on a charge potential (U _h6 ) for the development of the charge image (LB2) sets. Method according to Claim 10, in which the charge potential (U _h6 ) corresponds to the initial potential (U _a ). Method according to claim 9 or 10, in which after being transhipped by the transhipment unit ( 12 ) in the subsequent printing unit (DE2) by the associated character generator ( 7 ) in an image area (BB) in which the two adjacent print images (DB1, DB2) are generated, the image area outside the preceding print image (DB1) is exposed to the inverse image of the preceding print image (DB1) and by the associated character generator ( 7 ) the charge image (LB2) of the subsequent print image (DB2) on the photoconductor ( 1 ) is produced. Method according to claim 9 or 10, in which after being transhipped by a transhipment unit ( 12 ) in the subsequent printing unit (DE2) by the associated character generator ( 7 ) in an image area (BB) in which the two adjacent print images (DB1, DB2) are generated, the border area (RB) of the subsequent print image (DB2) is exposed to the inverse image of the preceding print image (DB1) and by the associated character generator ( 7 ) the charge image (LB2) of the subsequent print image (DB2) on the photoconductor ( 1 ) is produced. Method according to Claim 11 or 12, in which the exposure of the photoconductor ( 1 ) with the inverse image of the preceding print image (DB1) by one after the character generator ( 7 ) arranged charge sensor ( 11 ) is regulated. Method according to claim 9 or 10, in which after being transhipped by the transhipment unit ( 12 ) in the subsequent printing unit (DE2) by the associated character generator ( 7 ) in an image area (BB), in which the two adjacent print images (DB1, DB2) are generated, the edge area (RB) of the subsequent print image (DB2) is exposed such that there is a charge Po tential (U _h6 ), which corresponds to the initial potential (U _a ). Method according to Claim 14, in which as a character generator ( 7 ) an LED character generator is used with the adjustable edge region (RB) by pointwise exposure as edge PEL exposure to the charge potential (U _h6 ) is reloaded. Method according to Claim 15, in which the width of the edge region (RB) is determined by the pointwise exposure by the character generator ( 7 ) is set. Method according to Claim 15 or 16, in which the intensity of the transposition in the edge region (RB) is determined by the adjustment of the intensity of the exposure of the LED's of the character generator ( 7 ). Method according to one of Claims 5 to 17, in which, in the printing units following a second printing unit (DE2), the photoconductor ( 1 ) by an intermediate exposure unit ( 15 ) is transferred to saturation, - the photoconductor ( 1 ) by a transhipment unit ( 16 ) is reloaded to a Umladepotential, the amount is higher than the initial potential (U _a ), - the photoconductor ( 1 ) by a further intermediate exposure unit or a character generator ( 17 ) of the associated printing unit to the charge potential which corresponds to the initial potential (U _a ), and by the character generator ( 17 ) the charge image (LB) of the respective print image is generated, - the charge image (LB) by a developer station ( 18 ) of the associated printing unit to the toner image of the respective print image is developed. Arrangement for carrying out a method according to one of the preceding claims, - in which, along a photoconductor ( 1 ) at least two printing units (DE1, DE2) are provided for the production of printed images (DB) arranged in series, each of which has a character generator ( 4 . 7 ) for generating the charge images (LB) of the images to be printed and a developer station ( 5 . 8th ) for coloring the charge images (LB) with toner on the photoconductor ( 1 ), in which the toner images (TB) are transferred to a printing material (AT) and are fixed there. - at which the developer stations ( 5 . 8th ) each have a jump roller ( 6 . 9 ) having a toner cloud in the developer gap between the photoconductor ( 1 ) and Jumpwalze ( 6 . 9 ) and at which a bias voltage is applied with a polarity, due to which the charged toner to the charge images (LB) on the photoconductor ( 1 ) to their coloring. Arrangement according to claim 19, in which units for intermediate exposure (between the printing units (DE1, DE2) 13 . 14 ) and transhipment ( 12 ) are arranged. Arrangement according to Claim 19 or 20, in which, within the printing units (DE1, DE2), between character generator ( 4 . 7 ) and developer station ( 5 . 8th ) each a charge sensor ( 10 . 11 ) is provided. Arrangement according to one of Claims 19 to 21, in which, along the photoconductor ( 1 ) a number of printing units (DE) corresponding to the number of colors to be printed are arranged, between which in each case units for intermediate exposure ( 13 . 14 ) and transhipment ( 12 ) are provided. Arrangement according to one of Claims 19 to 22, in which the character generators ( 4 . 7 ) LED character generators are. Arrangement according to one of claims 21 to 23, - in which a control circuit is provided, by which the charging of the photoconductor ( 1 ) by the character generators ( 7 ), - in which the charge sensors ( 10 . 11 ) the charge of the photoconductor ( 1 ) and deliver a measurement signal dependent thereon, - in which the measurement signal is compared by a comparison circuit (VG) with a discharge setpoint (SW) and the comparison generates a control signal (RG) which corresponds to a PI controller (RG) which supplies a control signal for the respective character generators ( 7 ), so that the photoconductor ( 1 ) is discharged to the setpoint.