DE2253899C3 - Continuous electrophotographic copying process with liquid development and transfer to a copy carrier - Google Patents

Description

The invention relates to a continuously feasible electrophotographic copying process, in which first electrostatic latent images, which are on a photoconductive and optionally a insulating layer of a recording medium are formed, developed with a liquid developer the liquid depth of the developer solution remaining on the layer is adjusted, then the developed images electrostatically on a copy support having an oil absorption coefficient greater than 50 seconds, which is calculated with the developer solution -, 0, transferred and fixed there, and then the layer is cleaned.

Many electrophotographic copying processes are already known in which electrostatic latent images are first created, then developed and -, -, then fixed. The development can take place with dry as well as with liquid developer materials. In some known methods, the electrostatic latent images are fixed directly on a layer of the original carrier material, so that the desired copy is created on this layer , transferred, where they are only then fixed; the (, ·> last-mentioned methods work with a transfer of the developed images.

In such known processes with transfer and liquid development (DE-OS 19 23 807; DE-OS 20 52 534 and DE-OS 2112 015) can indeed pictures of satisfactory quality, but other difficulties arise: for example, the Using smooth copy papers easily leads to an unstable fixation of the transferred image, being too note that in the case of transfer and liquid developer processes, the process of fixing is different proves to be more difficult than in the case of a dry-fixing method for other reasons alone

In order to create an improvement here, one has in the case of the method described in DE-OS 21 10409 the use of copier papers with particularly low oil absorption coefficients has been proposed. but This also meant that the difficulties in fixing indicated above could not yet be sure of be overcome, they occurred rather with the use of smooth paper (the traditional have such small oil absorption coefficients) continue to.

Proceeding from this, the invention is based on the object of improving a method of the type mentioned at the beginning in such a way that particularly clear images are obtained and good fixing of the images is ensured. According to the invention, this is achieved in such a method that the liquid depth of the developer solution remaining on the layer is set to 5 to 30 μm and that the copy carrier has a surface roughness of 30 to 150 seconds - measured by the Bekk method according to the conditions of the Japanese standard JIS P 8119 - has The mentioned Japanese standard is generally based on a measurement according to the Bekk method, as in principle from the article "Determination of the smoothness according to Bekk" by A. Proksch (Allgemeine Papierrundschau 44/1968, pp. 1366, 1368) It can be seen that according to the conditions of the said Japanese standard, a lever weight of I kp / cm ² (normal condition) is used and the time that elapses until the height of the mercury column of the apparatus used has dropped from 380 mm to 360 mm is measured Device carried out by appropriate pre-calibration or design so that the inflow of IO ml of air The mercury column drops by the stated value. The measured time span for this decrease can thus be viewed as a numerical measure for the roughness of the surface of the paper to be measured. For the measurements, ten clean and flat, flawless, square injection samples of the paper to be examined with an edge length not less than 50 mm are examined, their measured values are noted and the mean value is calculated

The method according to the invention makes it possible to reduce the effectiveness of the transmission and the Fixing compared to conventional methods as well as the resolution of the transferred images improve, with continuous and repeated use of the recording medium without difficulty possible isi. In the method according to the invention it was recognized that in addition to a certain oil absorption coefficient also another surface roughness range for the copy papers used Must be used in conventional papers with the required oil absorption coefficient is usually not given. Adjustment of the remaining developer solution to the required Depth and the use of the specified surface

level with the required absorption coefficient then ultimately leads to the desired success in the method according to the invention, the aimed particularly good fixation of the transferred image, a satisfactory drying speed o. the like, results. The inventive method leads to a surprisingly good resolution of the Transferred images compared to conventional methods - The measures according to the invention allow it also means that the record carrier is optimal in the interests of repeated use can be cleaned without damaging it, creating a "haze" on the over the entire surface. The inventive Process allows a continuous and continuous execution of the individual process steps one after the other, without thereby the The quality of the subsequent images would be impaired. The recording medium is made of a carrier material and composed of a photoelectrically conductive layer as basic components. Advantageously, will after the transfer process, the depth of the liquid remaining on the recording medium layer Developer solution set to 2 to 15μπι Es It is particularly advisable to check the depth of the liquid on the layer before transferring the developed Images remaining developer solution by flattening or flattening by means of a corona discharge to adjust.

The recording medium to be used for the method according to the invention should be at least the Have the properties listed below in order to be able to carry out the according to the invention particularly effectively Process to bring about: it should initially be impermeable and must not be in the developer (mainly in its carrier liquid) dissolve; he should have adequate resilience to electrical voltage to be able to hold the electrical charge, and it should be high have mechanical strength that allows them to be used repeatedly.

As with already known electrophotographic copying processes, the recording medium can be produced, for example, that an inorganic photoelectrically conductive material, for example ZnO, Se or CdS, organic photoelectrically conductive material such as N-vinylcarbazole and oxyadiazole, as well a photoelectrically conductive layer consisting of a dispersoid system of a photoelectrically conductive Material and a binder is composed, applied or vacuum deposited, or that an upper layer is provided on a photoelectrically conductive layer, or that on a photoelectrically Conductive material and / or a binder, a selected material is applied that the The requirements listed above are sufficient.

A recording medium made of at least one electrically conductive carrier material, a photoelectrically conductive layer and an insulating layer is composed. Such a a light-sensitive body is, for example, drum-shaped formed and either by vacuum evaporation of a photosensitive material on a drum-shaped support or by applying a flexible plate made of photosensitive material made around a drum-shaped carrier. Furthermore, others are common for electrophotographic Treatment stages necessary devices still in

placed near the drum to the photosensitive To treat recording bodies ISngs of a given work line. For example around the photosensitive body a corona discharge device, an exposure * or irradiation device and means for liquid development arranged to form visible images on the to form photosensitive recording body. It will also continue to be a corona charge squeezer or pressing device for controlling the depth of the liquid on the developer, a discharge or discharge device for transferring and a cleaning device for cleaning the photosensitive Body provided.

^{A liquid with an insulating effect greater than 10 9} Ωcm and composed of toner particles and a charge control center is particularly suitable as a liquid development! The mean diameter of the toner particles is between 0.5 and 10.0 μm, preferably between 1.0 and 5.0 μm, since smaller particles reduce the quality level during transfer and, with larger particles, the fine structure of the images is lost.

The contact of this liquid developer with the photosensitive surface of the recording medium makes visible the electrostatic latent images formed on the recording medium.

The recording medium is then brought to the next treatment stage, in which on its surface There is a large amount of insulating liquid as well as toner particles that make up the visible images to shape.

Since the presence of the insulating liquid is required during the transfer, a certain amount must be used this liquid be present on the surface of the recording medium. However, should be avoided become that this amount is large because then when transferring the developed images to the transfer material at the same time a flow or shifting of these images can occur, which means the resolution of the images is adversely affected. The recording medium is then converted into a Device for the corona discharge flat squeezing or pressing brought to the liquid depth of the to adjust the developer solution remaining on the surface of the recording medium.

When the images are transferred or transferred, there is a particularly suitable depth for the developer solution layer on the surface of the recording medium at about 5 to 30 μm, in particular at 10 to 20 μm. Tests have shown that a depth of less than 5 μπι a space between the recording medium and the copy medium, resulting in non-uniformity of the transferred images could lead. On the other hand, is the depth of the liquid wedge greater than 30 μπι, the copy medium is so saturated that the fixing and drying very difficult and the resolution in the direction of the transferred images is reduced.

The method according to the invention and the results that can be achieved therewith are described in more detail below to be discribed:

A mixed dispersoid consisting of iOÜg microcrystalline Cadmium sulfide, 10 g of a 50% solution of vinyl chloride-vinyl acetate copolymer in toluene and 80 g of toluene is applied to a 0.05 mm thick aluminum foil so that a 40 μ strong dried layer. There will be a 38 μ

strong film made of polyethylene terephthalate with a Epoxy adhesive with low curing temperature attached, sq that a three-layer photosensitive body is obtained. the The surface of the insulating layer of the above photosensitive body is made uniform by the Corona discharge charged at +7 kV. Then the surface with the original images will be under the simultaneous alternating current corona discharge at 7 kV exposed, whereupon the whole surface is exposed to light is exposed to obtain electrostatic latent images. On the other hand, a mixture of 3 g Dispersed rubber in ring form, 2 g of low molecular weight polyethylene, 2 g of carbon black and 30 g of xylene and kneaded in a ball mill for twelve hours, and then with a homogenizer in 11 one electrically insulating liquid (IsoparG) dispersed, which contains 40 mg of lecithin, thereby obtaining the liquid developer. The mean diameter the particle in this developer is 2 to 3 µ. Using this developer, the above electrostatic latent images are developed Clear images (density or blackness 1.7) are obtained on the surface of the photosensitive body. The developer solution remaining on the photosensitive body is about 60 μ thick.

Then the corona discharge flat press or smoothing with the discharge tension as shown in the table below to determine the liquid depth of the Surface of the photosensitive body to regulate remaining developerea. The pictures are through the corona transfer was transferred in about 0.25 s on a transfer paper that had an oil absorption coefficient of 135 s and a surface quality of 100 s. The images obtained are through Drying with warm air is fixed The blackening, the resolving power and the degree of drying The density of the images is measured with a reflection density meter. The degree of dryness is obtained from the ratio of the amount of liquid in the, multiplied by 100% Paper after drying is contained, to the amount of liquid that is in the paper immediately after the

Transfer is included, determined. The dryer used for this works with direct heating by means of infrared light (800W), the distance between the heating wall and the transfer paper 10 mm and the feeding speed of the transfer paper 100 mm / s.

Tension for
the corona
Discharge
Smooth Liquid wedge depth
before the transfer Blackening of the
transferred
Image Drying
Degree Dissolution
capital
(Lines) uniformity
of the transferred
Image kV in μ in% in mm 7.2 2 to 3 1.25 98 8th available 7.0 5 to 6 1.40 95 6.3 Don't feel any 6.5 10 to 12 1.47 91 6.3 no 6.2 18 to 20 1.55 85 6.3 no 6.0 28 to 30 , 65 80 5.6 rope 5.5 38 to 40 , 68 70 4.5 no

The smoothing or flattening by the corona discharge is carried out with a gold-plated tungsten wire of 0.06 mm Diameter carried out, the distance between the photosensitive body and the wire is about 10 mm

The optimal time for the transmission according to the invention is about 0.2 to 1.0 s, which is of the Developer and the transfer condition. The transmission materials should be in sufficient Dimensions to be resistant to loosening or have the properties of auto-oil absorption as a Absorption of the developer during the transfer is undesirable. Furthermore, the transfer materials should also have a smooth surface so you get better contact with the photosensitive body.

Accordingly, the transfer materials used in the present invention should have an oil absorption coefficient greater than 50 seconds or an anti-oil absorption property greater than 0.5 seconds. The surface roughness (or the surface smoothness) should be over 30 seconds, preferably between 50 and 150 seconds. The oil absorption coefficient appearing in the above expressions is defined as the time in seconds, measured by means of a stopwatch, in which the reflection images of a point light source, which ^{are reflected on the surface of a drop of 0.004 cm 3} Isopar G, dv on a horizontally held object to be examined, disappear A piece of paper is placed with an injector with a 1/3 subcutaneous injector needle (HS 0.5 + 0.02 to 0.5-0.01 mm outer diameter, 23 ± 1 mm length and 12 ° tip angle). In other words, this means that the period of time is to be understood in which a drop of liquid is completely absorbed into the paper to be examined. The anti-oil absorption property is expressed as the time in seconds in which a drop of Isopar G, applied in the same way as in the case of the determination of the oil absorption coefficient, the whole area (with a diameter of approximately 10 mm) of the paper makes the drop transparent, using a stopwatch to measure. The surface roughness is determined by the Bekk method (corresponding to the Japanese industrial standard JIS-P 8119).

When transmitting, about 20 bi ·; 5%, preferably about 30%, the liquid depth of 5 to 30 μ of the developer on the surface of the photosensitive Body in front of the. Transfer remain on the surface after transfer, d. H. about 2 to 15 μ depth or strength of developer solution. This is necessary

to avoid blurring of the transferred figures and to avoid developer stains to regulate the transfer material, the surface roughness and the anti-oil absorbency the transmission materials is taken into account.

After the transfer, the photosensitive body is transferred to a cleaning device, where the 2 to 15 μ deep liquid that lies on the surface of the light-sensitive body is left behind, is removed.

The cleaning can be done by pressing a blade, a roller or a brush against the photosensitive Body to remove the remaining solution. Cleaning should be done like this that the depth of the developing solution on the surface of the photosensitive body is less than 1 μ. For this purpose, the blade material made of polyurethane resin is expediently with a

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The invention is explained in more detail with the aid of the following examples.

Example I.

A light-sensitive body is produced by placing a solution on a 60 μ thick aluminum foil in toluene and chlorobenzene of 2,5-bis (p-diethylaminophenyl) -1, 3,4-oxadiazole as photoelectrically conductive material, polycarbonate (Yubin E 2000, Mitsubishi Resin Co.) as binder resin and Rhodamine B as sensitizer in a weight ratio of I: 1: O, OI5 is applied so that a film layer with a thickness in the dried state of 10 μ is obtained.

The surface of this photosensitive body becomes uniform with the corona discharge

CH,

O ₂ N

-5.5 kV and exposed to the original images so that electrostatic latent images are formed. The images are developed with a commercially available liquid developer, which results in the > Surface of the photosensitive body clear images are generated. Those on the surface of the photosensitive The body's remaining developer solution is approximately 60 μ deep. The depth of the liquid is about 15 μ adjusted by means of the corona discharge at 6.5 kV.

Then the transfer takes place in about 0.2 s through the Corona transmission on a transfer paper that has an oil absorption coefficient of 135 s and a Has smoothness of 100 to 120 s. This is followed by a Clean with a polyurethane blade so that the

1 ". Liquid depth is reduced to less than 1 μ.

The above process is carried out repeatedly. The results are satisfactory for every attempt, and one gets a clear and distinct one

Example 2

A photosensitive body is produced as in Example I, in which a 60 μ thick aluminum foil a toluene and chlorobenzene solution of 2,5-bis (p-dimethylaminophenyl) -1, 3,4-oxadiazole as a photoelectrically conductive material, an acrylonitrile-styrene copolymer resin (Estyrene A-20, Union Carbide Co.) as a binder resin and a coloring agent having the following Structural formula is applied as a sensitizer in a weight ratio of 1: 1: 0.015, so that a 10 μ thick dried film is obtained. The subsequent treatment corresponds to that of Example 1 and a clear and distinct duplicate is obtained.

CH, CH,

NO,

—CH-CH-CH - '

nC "H, - CIO ₄ nC ₈ Hi-

Example 3

A mixture of 150 ml of acetonitrile, the 4 g of copper (I) iodide and 30 ml of a 5% solution of Containing polyvinyl formaldehyde is 90 μ thick Polyäthylenterephthalp'.platte applied and dried, so that the surface of the plate is electrically conductive. Then a solution is applied to the surface of the plate applied with 3 g of vinyl acetate resin per 500 ml so that a 6 μ thick dried film is obtained. On this product, the solution of the following is obtained Composition applied so that you get a 7μ thick dried film and a double layer light-sensitive body is created. The composition consists of 2 g poly-N-vinylcarbazole, 2 mg 2,4,7-trinitrofluorenone, 5 mg 33'3 "-Tricarbazo'iyimethylchlorid and 50 mg of monochlorobenzene.

The surface of this photosensitive body becomes uniform by corona discharge at +7.0 kV loaded and exposed with the original images, whereby electrostatic latent images are formed. The electrostatic latent images are created with a known liquid developer developed so that one clear images on the surface of a photosensitive Body receives. Then the liquid depth on the photosensitive body is reduced to about 15 μ by the Corona discharge set at -6.5 kV and the

-.0 images are transferred to a sheet of paper, the Oil absorption coefficient 135 s and its smoothness 100. amounts to. This is followed by cleaning with a blade. The above procedure is repeated. The results obtained are as good as those of the

Example 1. Example 4

The surface of a well-polished aluminum drum is μ by vacuum evaporation of 99.999% ethyl pure selenium to a thickness of 50 to 60 under a vacuum of 2 10 ~ ⁵ mm Hg χ to 5, and plated at a base temperature of 65 ° C, so that A double-layer photosensitive body is obtained. The surface of the photoelectrically conductive layer is then uniformly charged by the corona discharge at -t- 7 kV and exposed to the original images, so that electrostatic latent images are formed. The images are made in the same way as in Example 1 with

a liquid developer so that clear images are obtained on the surface of the photosensitive body. As shown in Example 1, the depth of the liquid on the photosensitive body is adjusted to about 20 µ by using the corona discharge at -6.2 kV. The images are then transferred to a sheet of paper, which has an oil absorption coefficient of 135 s and a smoothness of 110 s hr »This is followed by cleaning with a rotating brush so that the depth of remaining in the developer solution is reduced to less than 1 μ is. The above procedure is repeated and, as in Example 1, good results are obtained.

When the drum, the surface of which is plated with selenium by vacuum evaporation, is used as a photosensitive body and the development is carried out with a liquid developer, the surface material of the photosensitive body is rapidly converted into a crystalline form which iinni'mrtin t the image formation \ 'f | fit

When cleaning, in which the depth of the liquid on the photosensitive body is reduced to below 1 μ by treatment with a blade, roller or brush, however, the crystallized layer is likely to be deposited on the surface of the liquid together with the liquid developer photosensitive body removed. This prevents the photosensitive body from being deactivated due to the crystallization of the surface layer, and images of good quality are obtained. m

Example 5

A mixture consisting of 100 g of microcrystalline cadmium sulfide, 10 g of a 50% solution in Toluene from vinyl chloride-vinyl acetate copolymer r> and 80 g of toluene, is 0.05 mm thick Aluminum foil applied so that a 40 μ thick dried film is obtained. With an epoxy resin adhesive, which cures at low temperature, is still a 38 μ thick polyethylene terephthalate film applied to obtain a triple-layer photosensitive body. the Surface of the insulating layer of the photosensitive body becomes uniform by corona discharge + 7 kV charged and exposed with the original images, with the AC corona discharge at the same time takes place at 7 kV. Then "the surface is exposed to the light uniformly, so that one Preserves electrostatic latent images. Then a mixture consisting of 3 g of ring rubber (cyclic rubber), 2 g of low molecular weight polyethylene, 2 g of carbon black and 30 g of xylene, dispersed and twelve Kneaded for hours with a ball mill and then immersed in an electrically insulating liquid (Isopar G) dispersed, which contains 40 mg of lecithin with a homogenizing agent, creating a liquid developer When this developer is used, the above electrostatic latents become Images are developed so that clear images can be obtained on the surface of the photosensitive body The depth of the developer solution on the surface is about 60 μ.

The corona discharge is then carried out at 6.4 kV by the depth of the developer solution on the Reduce the surface of the photosensitive body to 15 μ. Then the images are processed in 0.25 s by the Corona transfer method transferred to a transfer paper that has an oil absorption coefficient th of 150 s and a smoothness of 100 s, the images being dried with warm air. You get so extremely clear and well fixed images.

The depth of the developing solution remaining on the photosensitive body after transfer is about 5 μ. This thickness is reduced to less than 1μ by cleaning with a polyurethane blade decreased. The process is carried out repeatedly. The results obtained are always good.

Example 5

A zinc oxide resin paste composed of the following components is applied to a 0.05 mm thick aluminum foil applied with a piece of wire so that an 18 to 22 μ thick dried Coating film is formed. This gives a two-layer photosensitive body.

The Zinkoxydharzpaste contains in parts by weight per 100 parts photo electrically conductive zinc oxide, 375 T _e; j _e Polyvinylb'jlyla! (BM-2, Sekisui Chemicals Co.), 125 parts of acrylic resin (LR-472, Nippon Reichhold Co.), 700 parts of isopropyl alcohol, 800 parts of xylene and -3 parts of red bengal (Rose Bengale) in methanolic solution.

These components are mixed in a ball mill and then made with a mixed solvent Isopropyl alcohol and xylene dilute until the particle size is reduced to about 600 cp. The thus obtained Mixture is applied to the aluminum foil.

The surface of this photosensitive body becomes uniform by the corona discharge - 7.4 kV charged and exposed to the original images so that electrostatic latent images are obtained. On the other hand, the carbon black-resin mixture according to Example 5 is mixed with a homogenizing agent in I 1 an electrically insulating liquid (Isopar G, Esso Co.) containing 100 mg of cobalt naphthenate. The liquid developer thus prepared is used to develop the electrostatic latent images. The surface of the photosensitive body can become visible by using the so developed developer form clear images. The depth of the developer solution on the surface will be based on about 15 μ set by applying the corona discharge at + 7 kV. Then the images are through the Corona transmission transferred to a sheet of paper, which has an oil absorption coefficient of 135 s and a Has smoothness of 120 s. This is followed by cleaning with a rotating brush. The procedure is repeated. The results are as good as those in example 1.

Example 7

In the same way as in Example 1, visible images are produced on a photosensitive body, wherein the depth of the liquid developer is about 60 μ

Then smoothing is carried out by the corona discharge at 7.0 kV, so that the liquid depth increases of the surface of the photosensitive body is set to 5 to 6 µ by using the corona transmission Then, in about 0.25 seconds, the images are transferred to a transfer paper having an oil absorption coefficient of 600 s and has a smoothness of 300 s. The transferred images are made with warm air dried Extremely clear and well-fixed images are obtained.

After the transfer treatment, the depth is as on the surface of the photosensitive body

ii

remaining liquid about 3 μ. This liquid becomes completely by cleaning with a polyurethane blade removed without leaving any appreciable amount of liquid on the photosensitive body.

Example 8

As in Example 5, visible images are formed on a photosensitive body, with the depth of the liquid developer is about 60 μ.

Then smoothing is carried out by the corona discharge at 6.0 kV to reduce the liquid depth on the Adjust the surface of the photosensitive body to 28 to 30 μ. Then the pictures are through Using corona transfer, transferring its oil absorption coefficient to a transfer paper in about 0.25 s 50 s and its smoothness is 50 s. The transferred images are dried with warm air. In this way, extremely clear and well-fixed images are obtained.

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of the liquid remaining on the surface of the photosensitive body is about 7 μ. This liquid is completely removed when cleaning with a polyurethane blade, without any noticeable amounts of liquid remain on the photosensitive body.

Example 9

As in Example 5, visible images are produced on a photosensitive body, with the depth of the liquid developer is about 60 μ.

Then the smoothing is carried out by the corona charge at 6.5 kV in order to reduce the depth of the liquid to the Adjust the surface of the photosensitive body to 10 to 12 μ. The pictures are then through Using corona transfer, transferring its oil absorption coefficient to a transfer paper in about 0.25 s 300 s and its smoothness is 200 s. The transferred images are made with warm air dried. Extremely clear and well fixed images are obtained.

After the transfer treatment, the depth is as on the surface of the photosensitive body remaining liquid about 4 μ, which is almost completely removed by cleaning with a polyurethane blade, the depth of the liquid on the photosensitive body is then less than 1 μ.

Example 10

As in Example 5, visible images are created on the surface of the photosensitive body, wherein the depth of the developer solution is about 60 μ.

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performed at 6.4 kV to reduce the liquid depth on the surface of the photosensitive body to 15 μ to adjust. Then, using corona transfer, the images are converted in about 0.25 s transferred to a polyethylene terephthalate film (Mylar), the oil absorption coefficient of which is oo s. the Transferred images are dried with warm air. Extremely clear and well fixed images are obtained. To of the transfer treatment is the depth of that remaining on the surface of the photosensitive body Liquid about 7 μ. This fluid becomes almost entirely by cleaning with a polyurethane blade removed, the depth of the liquid on the photosensitive body then being less than 1 μ.

Claims (3)

. Claims; 1. Continuously feasible electrophotographic copying process, in which initially electrostatic latent images formed on a photoconductive and optionally an insulating layer a recording medium are designed to be developed with a liquid developer, whereby the liquid depth of the developer solution remaining on the layer is adjusted, then the developed images electrostatically on a copy support having an oil absorption coefficient greater than 50 seconds, which is calculated with the developer solution, transferred and are fixed there, and then the layer is cleaned, characterized in that that the liquid depth of the developing solution remaining on the layer is 5 to 30 µm is set and that the copy carrier has a surface roughness of 30 to 150 seconds - measured by the Bekk's method according to the conditions of the Japanese standard JIS P 8119 - has. 2. The method according to claim 1, characterized in that after the Obertrpgungsvorgang The liquid depth of the developer solution remaining on the carrier layer is set to 2 to 15 μm will. 3. The method according to claim 1 or 2, characterized in that the liquid depth on the Layer before the transfer of the developed images remaining developer solution by smoothing or flat pressing is stopped by the corona discharge. π