DE2010097C3 - Development electrode in an electrophotographic copier - Google Patents

Description

The invention relates to a development electrode in an electrophotographic copier, which im Development area arranged opposite the photoconductive recording material to be developed is and due to the charge induced by the electrostatic charge image on one opposite to the Reference earth potential self-adjusting working potential the deposition of toner particles on the Affects recording material.

In electrophotographic copiers there is usually a cylindrical drum, whose jacket surface carries a photoconductive layer. in the In the dark, this layer is insulating, so that static charges on it do not pass through the metallic ones The base layer can flow off. The photoconductive layer is sensitized at the beginning of each copying cycle through an even electrostatic charge. In the imagewise exposure corresponding to the For the copy, the charge flows off in the areas of the photoconductive layer struck by the light. What remains is a latent electrostatic charge image corresponding to the original. This picture becomes visible made by developing with toner particles adhering to the charged sites. That on the drum developed image is electrostatically transferred from the photoconductive layer to the copy sheet and there fixed.

There are a number of development processes, for example under the names of cascade development, Powder cloud development, development with magnetic brush or liquid development are known are.

A problem that is inherent in all toner development processes is the so-called edge effect. With large, evenly tinted areas in original images or with large line widths for letters in texts, the edges are copied more heavily. Relatively few toner particles adhere to the interior of the surfaces because the static field of the latent image is more concentrated at the edges and relatively weak in the interior. One way to obtain good reproductions in these areas is the use of a <, ί developing electrode, which is disposed in the vicinity dei ¹ to developing layer. The mode of operation of the electrode is to generate an increased, uniform field over the entire area to be developed, so that the toner particles are now also attracted to the inner surface parts and contribute to the development. A problem with the use of a development electrode is that the static field is increased even in background areas of the copy, which should remain white per se. Although the potential in these areas is significantly lower than in blackened areas, the residual charges are then able to attract toner particles. This undesirable effect can be reduced by keeping the development electrode at a potential by means of an external voltage source which is higher than that of the residual charges in the background area of the copy. This prevents toner particles from sticking to the white areas of the copy. The potential is sufficiently lower than that in blackened areas that development there is not prevented. Attempts have hitherto been made in various ways to measure the surface charge and to adjust the bias voltage of the development electrode in accordance with the image content of the copy, but devices of this type require external voltage sources and complex measuring and control circuits.

A development electrode of the type mentioned is known from US Pat. No. 3,219,014. At this A magnetic brush development station is used. It becomes a non-magnetic Shield used to cover a relatively large area of the recording medium carrying the latent electrostatic image to cover, whereby the magnetic brush assumes an average potential that the electrostatic Picture on average corresponds to. The potential of the brush should be around or a little more than take on the value of the background potential and swim freely. To do this is provided that in addition to the possibility of grounding this electrode or connecting this electrode with a potential source there is a further possibility of connection, in that this third Connection is neither connected to earth nor to the potential source and is therefore free. Disadvantage of this The arrangement is the fact that when several electrostatic images are developed one after the other, the Electrode is charged to a higher and higher potential, since no discharge of charge can take place in between. After developing some images, correct development of the following images is no longer possible.

The object of the invention is to avoid this disadvantage and in a development electrode of to ensure such an electrode potential without the need for measuring and control circuits, that a perfect development of the latent electrostatic images is always possible and this Development is optimally designed depending on the individual latent image to be developed.

According to the invention, this object is achieved in that the electrode is connected to the earth potential via the Parallel connection of an ohmic resistor is connected to a capacitor.

The advantage of using one in their size as well Characteristic can be selected according to the electrical and mechanical conditions of the copier Parallel connection of resistor and capacitor consists in the fact that one equipped with it Copier is more economical to manufacture and operate and a greater degree of reliability

achieves as such that to achieve equally good copies with the above-mentioned measuring and control loops or similarly complicated devices to achieve a certain potential for development. treatment electrode is equipped. In addition, it is particularly important in the case of sequential manufacture of copies of different degrees of blackness achieved an improvement in the copy quality in that the occurrence of voltage peaks due to large differences in charge on one and the same electrostatic Charge image is optimally damped.

Embodiments of the invention are explained below with reference to the drawing.

Fig. 1 is a schematic side view of a first embodiment; F i g. 2 shows a second embodiment.

In Fig. 1, 11 denotes a rotatably mounted Drum with a photoconductive layer 13 on its outer surface, made for example of vitreous selenium or from a mixture of polyvinyl carbazole and a Lewis acid, below which one electrically conductive layer 15 is arranged. A latent electrostatic image is created on the photoconductor educated. The photoconductor is initially charged uniformly by means of, for example, a corona discharge device and then selectively discharged by the imagewise exposure. When turning further the exposed photoconductive layer comes to development station 17, where it is brought into contact is with toner particles, i. H. with charged, electroscopic and finely divided pigment powder particles. These are usually enveloped with a heat-softenable resin binder material, for example with a natural resin or an organic synthetic resin such as polystyrene or another polymer, Epoxy resins, rosin or their ester compounds. There are many combinations of this type possible in connection with dyes such as carbon black, so d; 3 a correspondingly colored image easily can be fixed on a copy sheet by heating.

The development station 17 can be of any suitable type, for example a cascade development device, a device for powder cloud development or a development unit with a magnetic brush. The illustrated development station 17 is a device with a magnetic brush, at which a steel cylinder 19 rotatably mounted on a shaft 21 is arranged, iL'r by not shown Funds can be driven. Inside the steel cylinder, along the axis, there are a number of Permanent magnets 18 arranged.

A toner blend suitable for magnetic brush development contains in addition to the Dye particles a carrier that is ferromagnetic and optionally, electrically conductive, for example Iron filings or steel granulate. The particles can be provided with a coating of resin to the To impart the appropriate triboelectric properties to carriers. So the toner particles take the w> desired charge with respect to the latent charge image to be developed and adhere to the Carrier particles as a result of electrostatic forces of attraction. The carrier parts are magnetic Attractive forces from the surface of the cylinder 19 h> held and form an Ar 'brush-like loops or bristles 23 made of carrier and toner particles exist. By rotating the cylinder 19, these bristles with the latent charge image in Brought into contact, the distance 29 between the photoconductive layer 13 and the surface of the Cylinder 19 is set so that the bristles 23 just touch the surface of the photoconductive layer. The charge image attracts the toner particles and away from the carrier particles, so that the toner particles adhere to it and thus the electrostatic latent image on the photoconductive layer 13 to develop. To limit the length of the bristles of the magnetic brush is above the cylinder 19 a doctor blade 25 arranged, which so the degree of contact of the magnetic brush with the photoconductive Layer 13 regulates. The gap 27 between the outer surface of the cylinder 19 and the case 25 is slightly wider than the distance 29 between the surface of the cylinder 19 and the photoconductive Layer 13. Usually the distance is on the order of a few tenths of a millimeter to about 5 mm. The conveyor 31 orings continuously fresh toner and carrier to the cylinder 19 so that the Bristles that have touched the photoconductive layer and consequently less or no toner contain more, are continually replenished with fresh toner particles.

The parts of the lateral surface of the cylinder 19 that are closest to the photoconductive layer 13 also act as a development electrode. Those moving past development station 17 Surface charges on the photoconductor not only cause charges on the outer surface of the cylinder 19 opposite polarity due to influence, but also because the developer always has at least one Has minimal conductivity, through direct charge transfer from the photoconductor to the development electrode. This "induced" charge is so strong that when cylinder 19 is released, it becomes floating To accept potential, d. H. when it is completely electrically isolated from its surroundings, the charge is like this Progress is that not enough toner particles from the latent charge image on the photoconductive will be attracted to the layer and the image will be underdeveloped. On the other hand, when the cylinder 19 is grounded then increases the development electrode effect not only the development of the image areas, but also reinforces the field above the background areas, so that these areas now attract toner from the carrier and cloud the background areas of the image or black.

As far as the arrangement has been described up to now, it is known per se. So far one has tried. those with it To avoid difficulties that arise by connecting the development electrode to an external one Voltage source and complicated control circuits had to be provided to control the potential of the development electrode set to such a value as to ensure satisfactory development of the images became.

In the arrangement according to FIG. 1, the cylinder is 19 grounded via an electrical impedance, which in this case consists of the line 34 and the resistor 35 consists. This circuit delays the discharge of charge from cylinder 19 and causes the cylinder a potential against earth «» takes as long as a electrostatic image is developed. However, this circuit allows some of the charge to drain away, so that the cylinder 19 assumes a potential which is less than that which it would assume if the cylinder

19 would be electrically isolated from its surroundings. Of the Opposition is so determined that just that Sets potential, which together with the surface charge density distribution caused by the influence causes the desired suppression of the cloudiness of the background areas. The size of the used Resistance depends on the potential of the photoconductor and can easily be determined empirically will.

The arrangement was used experimentally to develop latent charge images on the photoconductive layer 13, which corresponded to line art as well as half-tone originals and mixtures of both types, and wherein the resistance was varied from infinity to earth fault. When the resistance was infinite, ie the development electrode was at a floating potential. an iK'giitivc voltage vwi'i ctwd uOO - 750 Vüu ΰΠ uC-Γ developing electrode was measured and practically no image at all could be developed on the photoconductor by toner particles. If the electrode was directly earthed by removing the resistor. the image was fully developed, but the background areas became very dark. In the following table I values are entered for the indicated voltages measured at the development electrode, if you have a resistance of about! · ¹ O ³ to / u 10 ■ 10 "ohms was varied.

Table I.

resistance Induced tension on cylinder 19 (Ohm) (Volt) Grounded 0 1 ■ 10 « 100-300 2.0 · 10 « 125-425 3.33 ■ IO ⁸ 350-550 10.0 · 10 « 450-600 OO 600-750

From the values in Table I it can be seen that the voltage on cylinder 19 increases as the value of the Resistance is increased. The voltage varied by about 200 volts because of the total charge on the areas of the photoconductive layer 13, which is attached to the cylinder 19

15th

20th

30th

35

40

45 pass by, according to the ratio of the charged areas and the discharged areas of the charge image varied. As the voltage on the electrode increased, the images showed a progressive decrease in the background until a loss in the degree of filling was observed at 3.33 · 10 "ohms, which was even more pronounced at the 10 · 10" ohms value. The resistance with a value of 2.0 · 10 ⁸ ohms resulted in the best combination of good Fülkingsg: acl of the image quality and background suppression.

The voltage fluctuations of about 200 volts observed at each resistance value apparently did not affect the overall image, with the exception of when strongly opaque images and bar copies were to be developed side by side. In these chambers, a large, charged surface was caused by the passage of large charged surfaces on the electrode . To the UntCT development of the bar copy. This effect can be compensated for by damping the voltage fluctuation according to an embodiment of the invention according to FIG. 2. The cylinder 41 of a magnetic brush developing device is grounded through a resistor 43. A capacitor 45 is connected in parallel with resistor 43. The ⁷ basic values for the resistor and the capacitor can easily be determined empirically depending on the type of images to be developed. The voltage fluctuations in cylinder 41 caused by the inducing differently charged parts of the image were reduced by the capacitor, which attenuated the sharp voltage peaks that were otherwise observed when the resistor was used alone in the resistance alone caused fluctuations of about 200 volts. For example, the parallel connection of a capacitor 45 before 0.01 pFarad with a resistance 43 of 6.0 x 100 ohms in the time constant of which, parallel to the resistance 43. the contact resistance of the developer, resulted in an image with an excellent degree of filling and unobservable clouding of the background .

For better adaptability of the mode of operation, the impedance can be adjusted for the operator can be made, for example, by an adjustable resistor that is set to an empirical value can be, ie according to the type of images that are partially developed.

1 sheet of drawings

Claims (2)

Patent claims: 1. Development electrode in an electrophotographic copier, located in the development area arranged opposite the photoconductive recording material to be developed is and due to the charge induced by the electrostatic charge image on one opposite to the Reference earth potential self-adjusting working potential the deposition of toner particles on the Affects recording material, characterized in that the electrode (19) with the Ground potential via a parallel connection of an ohmic resistor (43) with a capacitor (45) is connected. 2. Development electrode according to claim 1, characterized in that the ohmic resistance (43) is designed to be adjustable. 2Q