EP0031075A2 - Cyclic electrophotographic copying process - Google Patents

Abstract

Cyclic electrophotographic copying process in which a charge pattern is generated on a recording medium by electrostatic charging and exposure and a toner image is made visible with pigmented developer liquid and transferred to a copy carrier, and in which the recording medium is subjected to cleaning on the surface with developer liquid and is fed to a new copying cycle which cleaning is carried out at intervals independent of the copying cycle, for example before and after a series of copies and at most after every second copying cycle and / or with a reduced application of developer liquid.

Description

The present invention relates to a cyclic electrophotographic copying method in which. a charge pattern is generated by electrostatic charging and exposure and a toner image is made visible with pigmented developer liquid and is transferred to a copy carrier, and in which the record carrier is subjected to cleaning on the surface with developer liquid and is fed to a new copying cycle.

It is known (DE-AS 21 36 998) to electrostatically charge the photoconductor layer of the recording medium in each copying cycle during the production of electrophotographic copies, to expose it imagewise, to develop the latent charge image formed by applying oppositely charged pigmented particles. The generated toner image is transferred to a copy carrier, such as paper, and fixed there. After the transfer, the recording medium is freed of residual toner and of remaining charges or cleaned. When using pigmented developer liquids, cleaning with the developer liquid is carried out by rinsing using a cleaning element, which can be a cleaning sheet made of elastic material, a rotating brush (FR-PS 2,000,397) or by guiding the recording tape through a cleaning chamber (DE- AS 12 37 901).

As already indicated, cyclically operating electrophotographic copiers contain, as the central component, a recording medium made of a photoconductor drum or a photoconductor tape with a photoconductor layer made of, for example, an organic photoconductor made of poly-N-vinylcarbazole and trinitro "fluorenone, which is located on a flexible carrier made of polyester film on a The photoconductor layer, for example made of inorganic material such as selenium, which may be doped, can also be located on a metal drum. The individual process stations are arranged around the recording medium. To clean the photoconductor layer, developer liquid from the reservoir is superficially applied to the photoconductor layer pumped and distributed and smeared with a foam roller and wiped with a wiping lip resiliently against the photoconductor layer as far as possible to dry Advantageously at an elevated point on the photoconductor path, so that the developer liquid can flow back from the cleaning station in a cascading manner into the lower-lying reservoir (DE-AS 21 54 892).

This is documented in a schematic and simplified arrangement by the attached FIG. 1, with the charging station 2, the imagewise exposure 3 and the development station with developer around the recording medium 1, shown as a photoconductor drum tion electrode 6 and developer liquid 4 are arranged in the developer tank 5. After the transfer of the toner image to the copy carrier 7, cleaning takes place in the cleaning station, which consists, for example, of a foam roller 8 and a wiper lip 9 made of solvent-resistant rubber. Developer fluid is pumped into the cleaning station by the pump 10. The developer liquid flows back into the developer trough 5 along the end faces of the recording medium.

The known cleaning technology has the disadvantage that the free cascading of larger amounts of developer liquid favors the discharge of dispersing liquid by evaporation, which may be greater than the discharge of liquid through the copy carrier, especially at elevated ambient or device temperatures. This is particularly true when aliphatic hydrocarbons are commonly used as dispersants. In addition, the developer liquid is adversely changed by the cyclical cleaning and cascading, which results in manifold deterioration of the copy quality, since the loss of dispersant disrupts the sensitive disperse system of specifically charged, pigmented particles and additives.

It was therefore an object of the present invention to clean the recording for cyclic electrophotographic copying processes Carrier to create, which counteracts the disadvantages described, and thus to provide a cleaning process that extends the life of the developer liquid and runs under more environmentally friendly conditions.

The solution to this problem is based on a method of the type described in the preamble of claim 1 and is characterized in that the cleaning is carried out at intervals independent of the copying cycle and / or under reduced developer liquid application. In a preferred embodiment, cleaning is carried out at most every second copying cycle.

It has surprisingly been found that, in contrast to the prevailing view and practice which has been practiced for years, it is not necessary to rinse completely with developer liquid in each copying operation. This is especially true for multiple copies. After the first or the first copies, the rinsing with developer liquid for a predetermined number of copies is reduced or even suspended during further copying. After the last copy, it is not mandatory, but advantageously rinsed again.

It is preferable to clean before and after a series of copies has ended.

This ensures that less developer fluid evaporates and the developer fluid does not is changed quickly as with the previous procedure.

The course of the method according to the invention is described with the aid of the attached table, in which for each copying cycle 1 ... to ... Z it is specified whether cleaning or rinsing is carried out with the full amount of developer liquid A used according to the prior art, or whether it is not rinsed according to the invention, ie whether rinsing is carried out with the developer liquid quantity zero (0).

Before copying, it is known to precede a preparatory phase (V) with one or more rinses A ... in which the record carrier is cleaned by full rinsing. Rinsing after commissioning is also necessary according to the invention. When starting after a long standstill, for example overnight, it is advisable to rinse fully even during the first copying cycles so that, for example, the foam roller 8 is well moistened, as indicated by method I. The further control of the flushing then depends on the respective copying conditions. In most cases, you can leave the rinse off for continuous copying, as indicated by Procedure II. Otherwise, after a predetermined number of copying cycles, the rinsing must be interposed simply according to procedure III or several times according to procedure IV.

After copying is finished, cleaning is preferably carried out completely. This can be done by single or multiple rinsing A ... in a run-on as specified in procedures I to IV.

Under favorable conditions, one flush A is sufficient for the last copy (procedure V). In difficult cases one will rinse the last or the last copies Z and in the wake N, for example as indicated in procedure I.

It was recognized that the required rinsing intensity among other things very much depends on the quality of the respective developer liquid. The developer liquids, in which deposited pigment particles can be redispersed relatively easily, require little or no intermediate rinsing and vice versa.

It is also advantageous to rinse with reduced amounts of developer liquid, for example half the amount. Depending on the respective requirements, you will only wash with reduced amount a (procedure VI) or in any combination with the full amount of wash A (procedure VII). Intermediate rinsing with reduced amounts a according to procedure VIII is often sufficient. Finer subdivisions with regard to the rinsing amounts can bring even smaller advantages. Accordingly, cleaning in a mixed manner is advantageously used in the process according to the invention Operating mode with exposure to different amounts of developer liquid.

The developer liquid or the developer liquid quantity for cleaning or rinsing can be controlled by switching a pump motor on or off or closing and opening a valve, expediently as a three-way valve, under position 10 of FIG. 1, with a return flow into the developer tank 5. The control circuit can be designed to be space-saving with the aid of microprocessor technology and can be actuated via a copy counter (not shown).

In addition to the redispersibility of the pigments in the developer liquids, the evaporation rate of the dispersant is also a criterion for the selection of the respective rinsing or cleaning process. In the case of rapidly evaporating dispersing liquids, intermediate rinses may be required more frequently because the remaining liquid film on the photoconductor layer dries noticeably after the transfer to the copy carrier 7 until it is cleaned. This is particularly true when aliphatic hydrocarbons are used as the dispersing liquid with evaporation numbers up to about 50 (ether has a comparatively evaporation number 1).

For this reason, dispersing liquids which do not evaporate significantly during the copying times are preferred according to the invention. Have such dispersing liquids Evaporation numbers that are greater than about 70, preferably greater than about 120.

This makes it possible to lower the evaporating portion of developer liquid in a particularly effective manner and to reduce the quality-reducing change in the developer liquid.

Although the method is described on the basis of a photoconductor drum, it can also be applied to a photoconductor belt arrangement if one prevents the developer liquid from getting onto the back of the photoconductor belt in a noticeable amount. By reducing the number of flushes, this risk is even reduced, so that the method according to the invention favors the use of photoconductor tapes in liquid development.

• In einem handelsüblichen Kopiergerät wurde mit einer Entwicklerflüssigkeit kopiert, welche als Dispergiermittel einen aliphatischen Kohlenwasserstoff im Siedebereich 160-180°C mit einer Verdunstungszahl von etwa 40 enthält.

The method according to the invention is described quantitatively using the following data:

• In a commercially available copier, copying was carried out with a developer liquid which, as a dispersant, contains an aliphatic hydrocarbon in the boiling range 160-180 ° C. with an evaporation number of about 40.

During continuous copying and switched off cleaning according to procedure I described, the total dispensing of dispersing liquid was reduced by 30 up to 40%, with 100 copies from 0.35 g / A4 copy to 0.22 g / A4 copy. The room temperature was 27 ° C.

With the developer liquid used, however, instead of previously (with cleaning switched on), 17,000 copies could now be made. The liquid film on the recording medium in the cleaning station was very thin with this dispersing liquid.

With a developer liquid which contains an aliphatic hydrocarbon in the boiling range 210 to about 260 ^° C. and an evaporation number of 680 as the dispersant, the copying process according to procedure I could be practiced safely without the risk of running dry.

In these experiments, the pump 10 was controlled to transport the developer liquid to the cleaning station.

The description of the invention is based on electrophotographic copying techniques. However, the invention is generally suitable without restriction for cleaning cyclically used recording media on which charge images are developed with developer liquids and where the recording media are cleaned after the transfer.

Claims (6)

1. Cyclic electrophotographic copying process in which a charge pattern is generated on a recording medium by electrostatic charging and exposure and a toner image is made visible with pigmented developer liquid and transferred to a copy carrier and in which the recording medium is subjected to cleaning on the surface with developer liquid and is fed to a new copying cycle , characterized in that the cleaning is carried out at intervals independent of the copying cycle and / or under reduced developer liquid application. 2. Copying method according to claim 1, characterized in that the cleaning is carried out at most after every second copying cycle. 3. Copying method according to claim 1, characterized in that cleaning is carried out before and after a series of copies. 4. Copying method according to claim 1, characterized in that one carries out the cleaning in mixed mode with exposure to different amounts of developer liquid. 5. Copying method according to claims 1 to 4, characterized in that the cleaning with a developer liquid is made, which contains a dispersant with an evaporation number greater than about 70. 6. Copying method according to claim 5, characterized in that the cleaning is carried out with a developer liquid which contains a dispersant with an evaporation number greater than about 120.

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