JP4988868B2 - Method for forming an adjacent printed image on a substrate using an electrophotographic printing apparatus - Google Patents

Description

Development of a charge image or latent image of an image to be printed on a charge image carrier, such as a photoconductor drum or photoconductor band, in an electrophotographic printing or copying apparatus using a toner jump method Are known (see, for example, Research Disclosure 331080; US 4 868 600). In this system, a toner cloud composed of toner particles is formed by applying an AC voltage or a DC voltage in an intermediate space between the developing drum (jump drum) and the charge image carrier (hereinafter referred to as a developing region). From this toner cloud, toner particles move to the charge image carrier in response to the charge image, thus coloring the charge image carrier. Multicolor printing requires that the charge image be continuously colored using toner particles of different colors. For this purpose, a corresponding number of developing stations can be arranged along the charge image carrier (see US 5 828 933; GB 2 343 144 A). In this case, when the toner cloud is formed in the development area according to the toner jump method, toner particles are also generated in the charge image carrier, and another toner layer formed in advance by the preceding development station. There is a risk that the will peel off at least partially. This degrades the quality of the previously printed color image and contaminates the developer mixture at this development station.
JP 10 186831 A discloses an apparatus and method for continuously forming printed images on a substrate in an electrophotographic printing apparatus. The sequence of this method is as follows:
In the first step, the photoconductor is charged to an initial potential of −600V, and in a subsequent second step it is recharged to −100V by exposure to form a first charge image. The charged image is colored with black toner in the first developing station, and at this time, a toner image having a potential of −200 V is generated on the surface (third step). In a subsequent fourth step, the photoconductor is exposed from the back, which changes the photoconductor potential to -300V, or changes the toner image potential on the surface to -150V, below the toner image. The potential of a photoconductor is similarly recharged and charged to -50V. In the fifth step, the photoconductor potential is -650V, the toner image potential on the surface is -620V, and the photoconductor region under the toner image is -350V. The surface of the photoconductor having the toner image is recharged in a recharging unit. In the sixth step, a second toner image is formed next to the first toner image. When the toner image is recharged, the photoconductor regions under the toner image are always recharged together.
US 5 828 933 A discloses a method in which a color image is formed from a color extract. These color extracts are collected in a color image on a photoconductor, for example a photoconductor band. For this purpose, four printing units are arranged along the photoconductor, for example with four developing stations for four color toners. After the charge image for the first color extract is formed on the photoconductor, the photoconductor is colored with the first color toner to produce a first toner image. The photoconductor moves to the subsequent printing unit. Before the first toner image reaches the second printing unit, the photoconductor having the first toner image has a second charge for subsequent color extracts in the region of the first toner image. The image must be processed so that it can be formed and colored with the toner of the subsequent color extract. For this purpose, at least one recharging unit is arranged between the printing units. The recharging unit recharges the photoconductor and toner image so that a charge image for subsequent color extracts can be formed on the photoconductor and subsequently colored with toner. US 5 579 100 A discloses a printing device according to US 5 828 933 A. In these two publications, the toner image in the photoconductor area under the toner image is always along with the photoconductor area around the toner image, as well as recharging the previously formed toner image. Recharged together.
US 5 438 401 A discloses a method for continuously forming a printed image on a substrate in an electrophotographic printing apparatus. The photoconductor is first charged to an initial potential and subsequently discharged by exposure on the charge image for the first toner image. In subsequent steps, the charge image is colored with a first color toner. Subsequently, the photoconductor and the first toner image are recharged so that the surfaces of the photoconductor and the first toner image are at an initial potential, and the photoconductor area under the toner image is similarly recharged. As a result, the voltage drop in the toner image does not change. In addition to the first toner image on the photoconductor, a charge image of the second toner image is formed by exposure and discharge. Since the charge image is colored with the second color toner so that the potential difference between the two toner images is small, there is a risk that the first color toner will reach the development station for the second toner. small.
In JP 2002 023521 A, an image having a clear boundary is formed by an electrophotographic printing machine. For this reason, the area between the two toner image areas on the photoconductor is not electrostatically discharged. Therefore, a high potential exists between the toner images, and this potential prevents the toner of the toner image from moving to the subsequent toner image.

The problem on which the present invention is based is that the toner image already present on the charge image carrier is not influenced by the subsequently formed toner image, for example during continuous printing, which causes subsequent development stations to become contaminated. Is to provide a way that is not.
In particular, this method is such that a toner cloud is formed in the development area, the charge image is colored, and the toner image already present on the charge image carrier by the toner cloud is not allowed to be affected, for example during color printing. It can be used for toner jump development of charge images on charge image carriers.

  This problem is solved by the configuration described in the characterizing portion of claim 1.

  A printing unit is arranged on the same side along a rotating photoconductor that is pre-charged to the initial potential, and each printing unit follows one code generator and a friction jump (Tribo-Jump) method. A developing station that operates, each of which forms a charge image of a printed image on the photoconductor, the charge image being disposed in the development station, and a pre-voltage (bias voltage) When the toner image is colored with the toner charged by the applied jump drum and becomes a toner image, the toner image formed by the first printing unit is printed in the subsequent printing unit by the toner of the first toner image. The toner in the unit is peeled off and damaged by reaching the development station of the subsequent printing unit. There is a danger.

  In the following, in order to explain the means for solving this problem, a printing apparatus including two printing units arranged in succession will be described as an example. In this printing apparatus, the first printing unit forms a charge image to be printed on the first toner image of the first printing image, and the subsequent second printing unit performs the second printing image of the second printing image. A second charge image to be developed is formed on the toner image. However, this does not limit the solution to a printing apparatus having two printing units, and the solution can also be applied to a printing apparatus having more than two printing units.

  The charge image (of the first toner image) developed with the toner by the first printing unit is transferred to the developing station of the subsequent printing unit from the first toner image. After leaving the printer and before reaching the subsequent second printing unit, the toner of the first toner image is prevented from moving to the development station of the second printing unit by the recharging unit together with the photoconductor. It can be reduced by being recharged to a recharge potential. This achieves that the toner of the first toner image does not reach the developing station of the subsequent printing unit.

  Developments of the invention are described in the dependent claims.

  In the first embodiment of the invention, the recharge potential corresponds to the initial potential of the photoconductor.

  Further improvements can be achieved if the absolute value of the recharge potential is chosen higher than the initial potential of the photoconductor.

  If the photoconductor having the first toner image is discharged again by the intermediate exposure unit before recharging, and subsequently charged by the recharging unit to a recharging potential whose absolute value is greater than the initial potential. The fixing of the first toner in the photoconductor is significantly enhanced and this toner is sufficiently prevented from moving to the development station of the subsequent printing unit.

  This effect is further enhanced when the photoconductor is discharged to saturation by the first intermediate exposure unit and the absolute value of the potential of the toner image is greater than the recharge potential of the photoconductor after recharging.

  The development of the second charge image by the subsequent printing unit allows the photoconductor to be brought to a potential corresponding to the initial potential of this photoconductor by the second intermediate exposure unit before reaching the subsequent printing unit after recharging. It can be improved by being discharged up to.

  This can be achieved as expected if the potential of the photoconductor is measured by the charge sensor after the second intermediate exposure and the intermediate exposure is controlled by the measurement signal.

  The code generator of the subsequent printing unit obtains optimum results by bringing the code generator to the optimum potential for the formation of the charge image in the region where the second charge image is to be generated in the photoconductor. This potential may be, for example, an initial potential.

  The goal is that in the first method, the area where the first printed image and the second printed image are to be formed after the photoconductor is recharged by the recharging unit of the code generator of the subsequent second printing unit. The image area outside the first toner image is exposed with a reverse image of the first charge image, and a charge image of the second print image is formed on the photoconductor in this image area. Can be achieved. It is particularly advantageous if the second print unit code generator only exposes the reverse image of the first charge image in the edge region of the second charge image. The exposure of the photoconductor with the reverse image of the first charge image can be controlled and adjusted using a charge sensor located downstream of the code generator.

  It is advantageous when the area around the previously formed toner image is not exposed during the reversal exposure. When an LED code generator is used as the code generator, reverse exposure is performed as pixel-by-pixel exposure, and the area around the toner image formed in advance is adjustable and excluded from pixel-by-pixel exposure. be able to.

  For example, the exclusion of exposure for each pixel around the toner image formed in advance is 1 PEL.

  The target is that in the second method, an LED code generator is used as the code generator, and the edge region of the second charge image is adjustable by using this code generator. PEL exposure) can be achieved when it is recharged to an optimal charge potential, for example an initial potential, for development of the second charge image. In this solution, the width of the edge region can be adjusted by pixel-by-pixel exposure using a code generator. Furthermore, the intensity of recharging in the edge region can be defined by adjusting the intensity of the LED exposure of the code generator. The formation of the second charge image does not depend on the first toner image, and a printed image having a fine code and pattern can be formed better.

  Code generation is performed for a plurality of adjacently arranged print images in which a part of a toner image of a print image formed in advance is arranged side by side so as to enter an edge region of the subsequent print image The code generator is exposed so that the device does not expose the portion of the toner image that was previously formed.

  The present invention will be described in detail based on the embodiments shown in the drawings.

1 shows an electrophotographic printing apparatus. In principle, a pulse graph is shown in which the potential on the photoconductor is plotted over time when two consecutive printed images are formed by two printing units without using the present invention. FIG. 3 shows a pulse graph corresponding to FIG. 2 representing the potential on the photoconductor when the photoconductor is recharged during the formation of two printed images by two printing units. FIG. 3 shows a pulse graph corresponding to FIG. 2 showing the potential in the photoconductor when the photoconductor is overcharged during recharging. FIG. 3 shows a pulse graph corresponding to FIG. 2 showing the potential in the photoconductor when the photoconductor is further exposed before recharging. FIG. 3 shows a pulse graph corresponding to FIG. 2 showing the potential in the photoconductor when the photoconductor is further subjected to intermediate exposure after recharging. FIG. 3 shows a pulse graph corresponding to FIG. 2 representing the potential in the photoconductor when the code generator of the second printing unit is controlled by a charge sensor. FIG. 6 shows a first printed image after being reverse exposed with a first charge image. FIG. FIG. 9 shows a first method for reversal exposure according to FIG. An advantageous refinement of the first method is shown. The 1st print image and 2nd print image in case a 2nd print image is reversely exposed only in an edge area | region are shown. 12 shows a second method for realizing the embodiment of FIG. An improved form of the second method is shown. FIG. 3 shows a pulse graph corresponding to FIG. 2 representing the potential in the photoconductor when more than two toner images are successively formed on the photoconductor according to the present invention. 2 shows a control circuit for controlling the sign generator of the second printing unit.

  FIG. 1 shows the basic structure of an electrophotographic printing apparatus. In this embodiment, two printing units DE1 and DE2 are arranged around the photoconductor 1, which is a photoconductor belt in FIG. 1, and these printing units DE1 and DE2 are used for coloring with toner. Formed charge images can be formed on the photoconductor 1 and these charge images are arranged side by side. The photoconductor 1 is moved in the direction of arrow 2. The photoconductor 1 is cleaned by the cleaning unit RE before reaching the printing unit DE1. The cleaning unit RE is located behind the transfer station US where the toner image is transferred to the substrate AT.

Each printing unit DE1, DE2 has code generators 4, 7 and developing stations 5, 8. For example, LED code generators can be used as the code generators 4, 7, which discharge the photoconductor 1 by exposure according to the image to be printed, thereby developing it at a development station. A charge image of the image is formed. As the developing stations 5 and 8, developing stations 5 and 8 operating in accordance with a friction jump (Tribo-Jump) system can be used. This mode of operation is known but will be explained again below:
After mixing by the magnetic drum, the developer is supplied to the jump drums 6 and 9 as the developing drum from the developer mixed liquid composed of the carrier and the toner, and the jump drums 6 and 9 receive the charged toner from the magnetic drum. The toner is supplied to a developer gap formed between the jump drums 6, 9 and the photoconductor 1, where a toner cloud is generated, from which the toner is photoconductive to color the charge image. Reach 1 In order to assist the transfer of toner from the toner cloud to the photoconductor 1, the jump drums 6, 9 are preloaded to generate an electric field between the jump drums 6, 9 and the charge image on the photoconductor 1. That is, a bias voltage is applied, and the charged toner is moved toward the charge image based on this voltage.

In operation (see FIG. 2), the optical conductor 1 is first charged to the initial potential U _a by the charging unit 3. Subsequently, the photoconductor 1 moves to the first printing unit DE1. In the first printing unit DE1, the charged photoconductor 1 is exposed by the code generator 4 in accordance with the image to be printed by the first printing unit DE1 (first printed image), thereby A first charge image LB1 of the first print image to be printed is formed on the photoconductor 1. The charge image LB1 is colored with toner at the first developing station 5 of the printing unit DE1 to become a toner image TB1. A charge sensor 10 can be provided between the code generator 4 and the development station 5, by which the charge on the photoconductor 1 is measured, depending on which the exposure and charging unit by the code generator 4 is measured. 3 is controlled.

  In the second printing unit DE2, the photoconductor 1 is exposed by the second code generator 7 according to the second print image to be printed, and the photoconductor 1 is discharged accordingly. The charge image LB2 formed by the second printing unit DE2 is located in the vicinity of the first toner image TB1. The second charge image LB2 is developed by the second developing station 8 to become a second toner image TB.

  The two toner images TB1, TB2 formed on the photoconductor 1 by the printing units DE1 and DE2 are transferred to the substrate, for example paper, in a known manner at the transfer station US and subsequently fixed in a known manner.

  Another functional unit can be arranged along the photoconductor 1 to improve the quality of the printed image. A recharging unit 12 can be provided between the printing units DE1 and DE2 in order to recharge the photoconductor 1 behind the printing unit DE1. Furthermore, in order to discharge the photoconductor 1, an intermediate exposure unit 13 can be provided between the first printing units DE1 and DE2. This intermediate exposure unit 13 can be arranged in front of the recharging unit 12. Further, another charge sensor 11 can be provided between the code generator 7 and the developing station 8 of the second printing unit DE2, and the second code generator 7 uses the measurement signal of the other charge sensor 11 to measure the charge. Recharging by the exposure and recharging unit 12 can be controlled. Finally, a second intermediate exposure unit 14 may be arranged between the recharging unit 12 and the second printing unit DE2 so that the photoconductor 1 can be further exposed according to the application case. it can.

  The functions of the printing apparatus will be further described with reference to FIGS. FIGS. 2 to 7 and 14 are plots of the course of the potential in the photoconductor 1 when various units are used along the photoconductor 1 to form a printed image by the printing units DE1 and DE2. Shows a pulse graph. In this embodiment, it is assumed that the toner is negatively charged and the potential at the photoconductor 1 is negative as well. However, the present invention can also be used when the toner is positively charged and the potential at the photoconductor 1 is positive. FIGS. 2 to 13 only show how two printed images of different colors are formed side by side by the printing units DE1 and DE2. FIG. 14 shows the case where a third printed image is formed on the photoconductor 1 by another printing unit (not shown in FIG. 1). In FIGS. 2 to 7 and 14, a plurality of functional units of the printing apparatus are suggested above the pulse graph that affect the photoconductor 1 with respect to the matters described.

FIG. 2 shows the starting situation when toner images TB of two printed images are formed side by side on the photoconductor 1 by two printing units DE1 and DE2 without using the present invention. FIG. 2 shows problems that occur during operation without using the present invention. First, the charging unit 3 charges the photoconductor 1 to an initial potential U _a , for example, about 500V. Subsequently, the photoconductor 1 is discharged to a discharge potential U _el of, for example, about −40 V according to the image to be printed by the code generator 4. The charge image LB1 formed at this time is colored by the first color toner T1 at the developing station 5 in the next step. This process is supported by the fact that the bias voltage at the jump drum 6 is, for example, about −300 V, thereby supporting the movement of the negatively charged toner T1 to the charge image LB1. As a result, a first toner image TB1 represented symbolically by the two toner particles T1 is generated. The toner image TB1 has a potential U _tl that is more negative than the discharge potential U _el . The photoconductor 1 is further moved towards the printing unit DE2. In the printing unit DE2, photoconductor 1 located in the vicinity of the toner image TB1 is exposed according to an image to be printed by the code generator 7, thereby being discharged to the re-discharge potential U _el, charge image LB2 Arise. Subsequently, the charge image LB2 is colored with another color toner T2 at the developing station 8 to become a toner image TB2.

When the toner image TB is formed according to FIG. 2, several problems occur. That is,
-Since the toner image TB1 also passes through the developing station 8, at the developing station 8, the toner T1 is melted from the toner image TB1 by the toner cloud composed of the toner T2 existing in the developer gap, and the melted toner T1 is transferred to the developing station 8. Reach and contaminate the developer mixture.

  -The melting of the toner T1 from the toner image TB1 causes the toner image TB1 to deteriorate or be completely destroyed.

  -Furthermore, an enhanced background is formed in the first toner image TB1, and thus in the first printed image, which also occurs in non-recharged areas of the photoconductor 1. This is suggested by the lack of toner T1 in toner image TB1 and toner T1 in toner TB2 in FIG. 2 and the subsequent figures.

  The disadvantages of the scheme according to FIG. 2 are avoided with various measures according to the invention which are used depending on the desired quality of the printed image. These measures are described below.

The first measure will be described with reference to FIG. In this measure, after the formation of the first toner image TB1, the photoconductor 1 is again charged together with the toner image TB1 by the recharging unit 12 to, for example, the recharging potential U _hl corresponding to the initial potential U _a , The potential of the image TB1 is accordingly increased to U _t2 . Therefore, the potential of the toner image TB1 is negative as compared with the bias voltage of the jump drum 9. Due to the relatively high negative toner potential of the toner image TB1, on the one hand, the adhesion to the photoconductor 1 is increased, and on the other hand, the force with which the toner T1 repels the toner T2 is increased. As a result, less toner T1 melts from the toner image TB1 to the developing station 8.

According to FIG. 4, the photoconductor 1 is charged to the recharging potential U _h2 by the recharging unit 12, and the first toner image TB1 is charged to the potential U _t3 that is more negative than the initial potential U _a . In the case of (overcharge of toner image TB1), further improvement is achieved.

Thereby, negative charging of the toner image T1 is achieved, and the adhesion to the photoconductor 1 is increased. In addition, a relatively large potential difference (relatively large repulsive action) between the first toner image TB1 and the second toner image TB2 in the second developing station 8 is achieved, and therefore the toner T1 of the first toner image TB1. Recharging is prevented. The photoconductor 1 can be charged by the recharging unit 12 to U _{h2 of} , for example, about −870V.

The solution according to FIG. 4 has the disadvantage that the photoconductor 1 is overcharged and the development of the second toner image TB2, and thus the development of the second print image DB2, deteriorates especially when it represents a delicate code. Have. In order to prevent this, measures according to FIG. 5 can be taken. In FIG. 5, the photoconductor 1 is exposed to the first intermediate exposure by the intermediate exposure unit 13 before being recharged, thereby being further discharged in a saturated state, for example to U _es ≈20V. In this case, the potential of the toner image TB1 can be discharged to, for example, U _t4 ≈100V. Here, when the photoconductor 1 is charged again by the recharging unit 12, the toner image TB <b> 1 is negatively charged compared to the photoconductor 1. For example, U _h3 ≈−750V and U _t5 ≈−800V. Accordingly, overcharging of the photoconductor 1 is reduced. As a result, the movement of the toner T1 of the first toner image TB1 to the developing station 8 is prevented.

According to FIG. 6, further improvement is achieved when the potential of the photoconductor 1 is further reduced and the potential of the first toner image TB1 is not changed. This can be achieved by the photoconductor 1 being exposed to a second intermediate exposure by the second intermediate exposure unit 14 and discharged to a recharge potential U _h4 corresponding to the initial potential U _a. . In order to adjust the initial potential U _a again, the potential in the photoconductor 1 is measured via the charge sensor 11, and the second intermediate exposure unit 14 is set so that the potential of the photoconductor 1 becomes the initial potential U _a. Can be controlled. This prevents the toner T1 of the first toner image TB1 from moving to the developing station 8, and provides an optimal charge potential in the photoconductor 1 for developing the second toner image TB2. When the toner T1 of the first charge image LB1 is transparent to the light wavelength of the exposure of the second exposure unit 14, the overcharge of the toner of the first toner image TB1 is lost as well. In such cases, there are drawbacks to this solution.

The solution for this case can be seen from FIG. In FIG. 7, the second intermediate exposure is omitted. After intermediate exposure by the intermediate exposure unit 13, the toner image TB1 is recharged to the potential U _t6 by the recharging unit 12, and in this case, the potential of the photoconductor 1 is U _h5 . The second code generator 7 sets the potential of the photoconductor 1 to the recharge potential U _h6 , for example, the initial potential U _a in order for the second code generator 7 to form the second toner image TB. Be controlled. For this purpose, the code generator 7 can be controlled in different ways, thereby achieving different results. A method carried out at that time will be described with reference to FIGS. As an example, consider an image region BB where two printed images are to be formed in succession. In this regard, according to FIG. 7, first, a charge image LB1 for the first print image is formed by the code generator 4, and this charge image LB1 is developed in the developing station 5 to become a toner image TB1. Subsequently, a charge image LB2 for the second print image is formed by the code generator 7, and this charge image LB2 is developed at the developing station 8 to become a toner image TB2.

In the first method, after the formation of the first toner image TB1, the code generator 7 performs a process other than the first toner image TB1 in the image region BB where the first print image and the second print image should exist. The region is controlled to be exposed with a reverse image of the first charge image LB1. Subsequently, as shown in FIG. 6, a second toner image TB2 is formed, for which purpose the photoconductor 1 is discharged to about -40V. The principle of this reversal exposure is shown in FIG. 8, where the image area BB is shown around the first toner image TB1, and in this image area BB, the first toner image TB1 is shown in a single color. The other areas around the first toner image TB1 are hatched to indicate that exposure is performed using the reverse charge image LB1. The exposure of the area around the first toner image TB1 is performed by the second code generator 7. In the image area BB marked with a broken line, the recharge potential U _h6 is adjusted, and the charge image LB2 can be formed by the second code generator 7. The first method will be further described with reference to FIGS. 9a to 9c.

9a to 9c show the principle diagram of the image area BB. In this figure, the image area BB is divided into a plurality of squares, and these squares can be exposed for each pixel using, for example, an LED code generator. Each pixel (pixel) formed by the LED of the LED code generator 7 discharges a photoconductor for each pixel to generate a PEL (printed element) on the photoconductor 1, and this PEL is colored with toner. Print pixels (dots) are formed. The LEDs of the LED code generator 7 are controlled in a known manner to selectively form individual PELs (represented by squares) by exposure. In FIGS. 9a to 9c, the toner image TB1 is represented by four PELs. FIG. 9a shows the potential characteristics after development at the development station 5 (see FIG. 7). The potential in the hatched area is U _a , and the potential U _t4 in the toner image TB1 area is. The image area BB is charged to the potential U _h5 (see FIG. 7) by the recharging unit 12, and then exposed by the sign generator 7 with the reverse charge image LB1, and at the same time, the charge image LB2 is formed ( See Figure 9b). As a result, the reversely exposed region is discharged from the potential U _h5 to the potential U _h6 , for example, U _a , but the toner image TB1 is not affected. Therefore, the potential of the toner image TB1 is maintained (U _t7 = U _t6 ), while the potential of the toner image TB2 is U _t8 . FIG. 9c shows a region BB where two toner images TB1 and TB2 (squares each consisting of four PELs) are arranged side by side. An image region having a potential U _h6 exists around the toner images TB1 and TB2.

In the first method according to FIGS. 8 and 9, the edge area of the toner image TB1 is affected by exposure using the code generator 7, so that in this edge area the toner can move to the development station 8. There is a danger of having sex. By excluding the region BT around the toner image TB1 from exposure by the code generator 7, this danger can be avoided. Therefore, in this region BT, the potential is maintained at U _h5 and the potential difference from the charge image LB2 is also maintained.

Thereby, the movement of the toner T1 of the toner image TB1 to the developing station 8 is prevented. In an advantageous solution, it is preferable when the area BT corresponding to one PEL around the toner image TB1 is excluded from the reversal exposure. This solution is shown in FIG. Since FIG. 10a corresponds to FIG. 9a, the description is omitted here. From FIG. 10b, it can be seen that the image generator BB is exposed by the code generator 7 excluding the toner image TB1 and, for example, a region BT having a width of one PEL around the toner image TB1. As a result, the potential of the region BT around the toner image TB1 is maintained at U _h5, and only the other regions of the image region BB are discharged to the potential U _h6 . The result is shown in FIG. In FIG. 10c, two toner images TB1 and TB2 are arranged side by side, the potential of the region BT around the toner image TB1 is U _h5 , and the potential of other image regions BB other than the toner image TB2 is U _h6 .

  In the second method, exposure with the inverted first charge image LB1 is performed only in the edge region RB of the second charge image LB2 (see FIG. 11). In FIG. 11, an image area BB in which the first toner image TB1 and the second toner image TB2 are arranged side by side and only the edge area around the toner image TB2 is exposed by the code generator 7. It is shown.

When an LED code generator is used as the code generator 7, the edge region RB can be exposed pixel by pixel by this code generator. Each pixel (pixel) formed by the LED of the LED code generator 7 discharges the photoconductor 1 for each pixel to generate a PEL (printed element), and this PEL is colored with toner and printed pixels (dots). Form. Controlling the LEDs of the LED code generator 7 in a known manner selectively forming individual PELs (within squares) by exposure in the edge region RB, and thus discharging the edge region RB in an adjustable manner. I can. The width of the edge region RB can be adjusted by selecting the LED, and the degree of discharge can be adjusted by adjusting the intensity of exposure. This method has the advantage that the first toner image TB1 does not affect the subsequent toner image TB2. Furthermore, the photoconductor 1 can be discharged to a charging potential U _h6 that realizes optimum development of the charge image LB2 as expected. For example, the charge potential U _h6 can be adjusted to the initial potential U _a . By using this method, the toner T1 of the first toner image TB1 is prevented from moving to the second developing station 8.

This second method is illustrated in FIGS. 12a to 12c. Since FIG. 12 corresponds to FIG. 9a, description thereof is omitted here. FIG. 12b shows the exposure of the image area BB by the code generator 7, which discharges the edge area RB around the charge image LB2 to the potential U _h6 while the remaining image area BB has the potential U _h5. To be maintained. Of course, the edge region RB may have a different width. In this embodiment, the width of the edge region RB around the second charge image LB2 is equal to two PELs. The result is shown in FIG. Two toner images TB1 and TB2 are arranged side by side, the potential of the edge region RB around the toner image TB2 is U _h6 , and the potentials of the other image regions BB are U _h5 .

In the method according to FIG. 12, as an example, a part of the toner image TB1 exists in the edge region RB. When the edge region RB is exposed using the code generator 7, the edge of the toner image TB1 is also affected, and as a result, the toner T1 may move to the developing station 8. In this case, in order to further prevent toner damage at the edge of the toner image TB1, exposure of the edge region RB of the charge image LB2 by the code generator 7 according to FIG. 13 can be carried out. Since FIG. 13a corresponds to FIG. 9a, the description is omitted here. The exposure by the code generator 7 can be seen from FIG. 13b. The region of the toner image TB1 in the edge region RB is excluded from exposure. However, the discharge to the potential U _h6 remains maintained around the charge image LB2. For example, when the charge generator LB2 performs exposure for two PELs around the charge image LB2 and the toner image TB1 enters one PEL region in the edge region RB for two PELs, the charge image One PEL region between LB2 and toner image TB1 is exposed by the code generator 7. In this case, toner damage in the toner image TB1 is minimized.

  Therefore, the method according to the present invention can avoid the problem caused by the first toner image TB1 passing through the second developing station 8 as expected. Optimal when the toner image TB1 is overcharged and thus has a relatively high adhesion to the photoconductor 1 and at the same time a relatively large repulsion effect on the toner T2 used in the second development station 8 A simple solution is achieved. Via the charge sensor 11, the code generator 7 can be controlled and operated so that the photoconductor 1 is recharged to an optimum development potential, for example an initial potential.

Exemplary potentials for the method according to FIG. 7 are as follows:
Charging (3): U _a ≈−500V range: (−400V → −600V)
Exposure (4/7): U _el ≈−40V range: (−10V → −100V)
Development (5/8): Jump gap≈180 μm range (100 μm → 300 μm)
First intermediate exposure (13): U _e2 ≈−20V range (−10V → −100V)
Toner adhesion region: Recharging according to the light transmittance of the toner relating to the wavelength of (13) (12): U _h5 ≈−700 V range (−650 V → −950 V)
U _h6 ≒ -750V range (-700V → -1000V)
Second intermediate exposure (7): U _h6 ≈−500V range (−400V → 600V)
U _h7 (light transmittance) ≒ -500V range (-1000V → -600V)
U _h7 (light impermeability) ≒ -750V range (-700V → -1000V)
Reverse exposure: U _h4 ≈−500V range (−400V → −600)
The region having the toner T1 in the first print image DB1 is not affected by the reverse exposure.

  FIG. 14 shows a pulse graph of an example in which three printing units are arranged along the photoconductor 1. The first area (up to the vertical dashed line) corresponds to the course according to FIG. 7, after which a third printing unit (not shown in FIG. 1) is placed on the photoconductor 1 with a third printed image. A potential course in the case of forming the toner image TB3 is shown. First, the photoconductor 1 is discharged by the intermediate exposure unit 15, and then the recharging unit 16 performs recharging equivalent to that shown in FIG. 7 (recharging unit 12). In a subsequent step, the photoconductor 1 is discharged by the code generator 17 in response to the third print image to produce a charge image LB3, which is developed at the development station of the third printing unit and is a toner image. TB3 is generated. Since the process and the potential characteristics correspond to those in FIG. Thereafter, printed images arranged side by side can be formed by another printing unit according to the same principle.

  FIG. 15 shows a principle circuit diagram of a control circuit for the code generator 7, for example. The charge of the photoconductor 1 is measured by the charge sensor 11. The measurement signal is compared with the discharge target value SW in the comparison circuit VG. The generated control difference RD is supplied to a discharge controller RG, for example a PI controller, which controls the code generator 7, which is based on this control in the photoconductor 1 (for example in FIG. 7) Adjust the desired potential.

  The present invention has been described using an embodiment in which the toner is negatively charged and the potential at the photoconductor 1 is also negative. However, the present invention can of course also be used in embodiments using positively charged toner. Therefore, in the claims, the potentials in the photoconductor 1 and the toner image TB are shown as absolute values.

DE1, DE2 printing unit, RE cleaning unit, US transfer station, AT substrate, LB charge image, TB toner image, BB image area, RB print image edge area, BT toner image edge area, T toner, 1 Photoconductor, 2 moving direction of photoconductor 1, 3 charging unit, 4, 7, 17 code generator, 5, 8, 18 development station, 6, 9 jump drum, 10, 11 charge sensor, 12, 16 re charging unit, 13, 14, 15 intermediate exposure unit, VG comparator circuit, RG controller, RD control difference, SW discharge target value, the initial potential of the U _a light conductor, discharge potential of U _e photoconductor, U _t toner Potential, U _h Recharge potential of toner image

Claims (11)

In a method of forming an adjacent printed image on a substrate using an electrophotographic printing apparatus,
Photoconductor rotates is charged to an initial potential (U _a) along the (1), a plurality of printing units on the same side (DE1, DE2) are arranged, said printing unit (DE1, DE2 ) Each have one code generator (4, 7) and one development station (5, 8) operating according to the friction jump method,
In each printing unit (DE1, DE2), by exposing the photoconductor (1) by the code generator (4, 7), a charge image (LB) of a printed image is formed on the photoconductor (1). Forming,
The charge image (LB) is developed with charged toner by a jump drum (6, 9) disposed in the developing station (5, 8) and applied with a bias voltage,
Printing unit surface of the toner image formed by (DE1) (TB), after the passage of the printing unit (D1), and before reaching the subsequent print units (D2), the toner image (TB) the photoconductor outside with areas of (1), re-charged by the first re-charging unit (12, 16), where the toner image (TB) the photoconductor outside (1) Is recharged to a recharge potential (U _h ) having an absolute value at least as large as the absolute value of the initial potential (U _a ) of the photoconductor (1) , and the toner image ( The surface of TB) is recharged to a toner potential (U _t ) having an absolute value at least as large as the absolute value of the initial potential (U _a ) of the photoconductor (1) ;
After the surface of the toner image (TB) is recharged by the first recharging unit (12, 16), the toner image (TB) shows an area of the photoconductor under the toner image (TB). Method, characterized in that it is not recharged before passing through the subsequent printing unit ( DE2 ). The photoconductor (1) having the toner image (TB1) formed first is further discharged before the second charging by the first intermediate exposure unit (13), and then the recharging unit ( The method according to claim 1, wherein charging is performed to a recharging potential (U _h3 ) having an absolute value larger than the initial potential (U _a ) by 12). The photoconductor (1) is discharged in a saturated state (U _e2 ) by the first intermediate exposure unit (13), and the absolute value of the potential (U _t5 ) of the toner image (TB1) is obtained after the recharging. The method according to claim 2, wherein the photoconductor (1) has a recharging potential (U _h3 ) greater than that. Before reaching the subsequent printing unit (DE2) after recharging by the second intermediate exposure unit (14), the photoconductor (1) is brought to the initial potential (U _a ) of the photoconductor (1). The method according to claim 2 or 3, wherein the discharge is made to a corresponding potential (U _h4 ).   The method according to claim 4, wherein the potential of the photoconductor (1) after the second intermediate exposure is measured by a charge sensor (10) and the intermediate exposure is controlled by a measurement signal.   After recharging by the recharging unit (12), in the image area (BB) where two adjacent printed images are formed by the code generator (7) to which the succeeding printing unit (DE2) belongs, After the formation of the first toner image (TB1) formed in this manner, the image area (BB) outside the first toner image (TB1) formed in advance is changed into a charge image ( Exposure by reversal exposure using a reversal image of LB1), and a charge image (LB2) of a subsequent second print image is formed on the photoconductor (1) by the associated code generator (7). 4. A method as claimed in any one of claims 1 to 3.   The method according to claim 6, wherein a region (BT) around the previously formed toner image (TB1) is excluded from exposure during the reversal exposure.   After recharging by the recharging unit (12), in the image area (BB) where two adjacent printed images are formed by the code generator (7) to which the succeeding printing unit (DE2) belongs, After the formation of the first toner image (TB1) formed in this manner, the edge region (RB) of the subsequent charge image (LB2) is used by using the reverse image of the charge image (LB1) formed in advance. 4. The exposure according to claim 1, wherein a charge image (LB 2) of a subsequent printed image is formed on the photoconductor (1) by the associated code generator (7). 5. Method. The exposure of the photoconductor (1) using a reverse image of the printed image (DB1) formed in advance is controlled by a charge sensor (11) arranged downstream of the code generator (7). Item 9. The method according to any one of Items 6 to 8 . In the image area (BB) where two adjacent print images are formed by the associated code generator (7) in the subsequent printing unit (DE2) after recharging by the recharging unit (12), The method according to claim 8 or 9 , wherein the edge region (RB) of the subsequent charge image (LB2) is exposed so as to produce a charging potential (U _h6 ) corresponding to the initial potential (U _a ). In the subsequent printing unit of the second printing unit (DE2), in order to form each subsequent printed image,
Recharging the photoconductor (1) in a saturated state by an intermediate exposure unit;
Recharging the photoconductor (1) by a recharging unit to a recharging potential having an absolute value greater than the initial potential (U _a );
The photoconductor (1) is recharged to the potential of the charge image (LB) of the respective printed image by a code generator of the printing unit to which it belongs or another intermediate exposure unit,
Developing the charge image (LB) by a developing station of the printing unit belongs, to form a toner image of each print image process of any one of claims 1 to 10.

Images