DE2010097A1 - - Google Patents

Description

Development electrode in an electrophotographic copier

The invention relates to a development electrode in an electrophotographic Copier, which is arranged in the vicinity of the photoconductive layer, and which, by means of its charge, the transfer of toner particles supported on the photoconductive layer for the development of latent charge images.

In electrophotographic copiers, it is usually cylindrical Drum present, the outer surface of which has a photoconductive layer wearing. This layer is insulating in the dark, like this

00984 T / 1635 '

that static charges on it do not overtake the metallic Can drain off the base layer. At the beginning of each copying cycle, the photoconductive layer is sensitized by a uniform one electrostatic charge. With the imagewise exposure corresponding to the copy template, the charge flows to the from Light struck areas of the photoconductive layer. What remains is a latent electrostatic that corresponds to the original Charge image. This image is made visible by development with toner particles that adhere to the charged sites. That Image developed on the drum 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 cascade development, powder cloud development, Magnetic brush development or liquid development are known.

A difficulty inherent in all toner development processes, is the so-called edge effect. For large, evenly tinted areas The edges are copied more heavily in image templates or with large line widths for letters in texts. Inside 4 «r surfaces relatively few toner particles adhere because of the static field

LK '.) - (ν? -01 i -2- ■

009841/1635

of the latent image is more concentrated at the edges and comparatively weak inside. One way of obtaining good reproductions in these areas too is to use a developing electrode which is placed in the vicinity of the layer to be developed. The function of the electrode is to create an increased uniform field over the entire area to be developed so that the toner particles now also on the inner surface parts are attracted and contribute to development. a problem with the use of a development "electrode is that even in background areas of the copy to. should remain white is, the static field is increased. Although * in the areas because the potential is much lower old in

The remaining charges are able to attract toner * particles. This undesirable effect can be reduced by keeping the development electrode at a potential which is higher than that of the residual charges in the background area of the copy by means of an external voltage source. So the adhesion of toner particles in the white remaining areas of the copy is prevented. The potential is sufficiently lower than that in blackened areas so that development is not prevented there. Up to now, attempts have been made in various ways to measure the surface charge and the bias of the development electrode in accordance with the image content of the copy

LE 9-69-013 009841 / ^ 35

to adjust. Facilities of this type, however, require external ones

Voltage sources and complex measuring and control circuits.

The invention avoids these disadvantages in a development electrode of the type mentioned above in that the electrode is designed to be self-charging at a floating potential and is grounded via an impedance.

Embodiments of the invention are based on the drawing explained below.

• - ί

Fig. 1 is a schematic side view of a first

Execution example.

Fig. 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 a mixture of polyvinyl carbazole and a Lewis acid, below which an electrically conductive layer 15 is arranged. On the photoconductor p / ird a latent electrostatic image formed. The photoconductor is initially evenly charged by means of, for example, an ei

LE 9-69-013 -4-

009841 / 163S

BATH

Corona discharge device and then selectively discharged through the imagewise exposure. As the rotation continues, the exposed photoconductive layer comes to the development station j17, where it is brought into contact with toner particles, ie 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 with an organic synthetic resin such as polystyrene or another polymer, epoxy resins, rosin or their ester compounds. Diverse combinations of this type are possible in connection with dyes such as, for example, "carbon black", so that a correspondingly colored image can easily be fixed on a copy sheet by heating.

The development station 17 can be of any suitable type, for example a cascade development facility, a facility for powder cloud development or a development unit with a magnetic brush. The development station 17 shown is a device with a magnetic brush, in which a steel one rotatably mounted on a shaft 21 Cylinder 19 is arranged by means not shown

can be driven. Inside the steel cylinder, lengthways a row of permanent magnets 18 arranged on the axis.

LE 9-69-.013 -5-

009841 /

BATH

A toner mix suitable for magnetic brush development contains, in addition to the dye particles, a carrier, is ferromagnetic and possibly electrically conductive,

for example iron filings or steel granulate. The particles can be provided with a coating of resin in order to give the carrier the appropriate triboelectric properties. . Thus, the toner particles take on the desired charge with respect to the latent charge image to be developed and adhere to the Carrier particles as a result of electrostatic attraction. The carrier particles are attracted by magnetic forces the surface of the cylinder 19 held and form a kind of brush-like loops or bristles 23, which are made of support and There are toner particles. By turning the cylinder 19 these bristles are brought into contact with the latent charge image, 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 sees the toner particles at and away from the carrier particles so that the toner particles adhere thereto and develop the electrostatic latent image on the photoconductive layer 13 in this way. To the length of the bristles of the To limit the magnetic brush, a doctor blade 25 is arranged above the cylinder 19, which so the degree of contact of the

LE 9-69-013 -6-

009841/1635

magnetic brush with the photoconductive layer 13 regulates. Of the Gap 27 between the outer surface of the cylinder 19 and the doctor blade is slightly wider than the distance 29 between the surface

Cylinder 19 and the photoconductive layer 13. Usually the distance in the order of a few tenths of a millimeter to about 5 mm. The conveyor 31 continuously brings fresh Toner and carrier to the cylinder 19 so that the bristles that the touching the photoconductive layer and consequently less or

^: "■■■ ■■■■. '" ■■. ■; ■■ -' - .. Λ

no more toner contained, continuously with fresh toner part- ^:

to be replenished. . ■ '.' * ■

Those of the photoconductive. Layer 13 closest parts of the The outer surface of the cylinder 19 also acts as a development electrode. Those moving past development station 17 Surface charges on the photoconductor induce charges on the surface of the cylinder 19- This induced charge is like this strong that when the cylinder 19 is released, a floating To accept potential, i.e. if he is aware of his surroundings is completely electrically isolated, the charging progresses so far, ' that not enough toner particles are attracted to the latent charge image on the photoconductive layer and the image

- · - ■ - <* ■■■

Underdeveloped. If other spits the cylinder 19 is grounded

then the development electrode effect not only increases the

LE9-69-013 -7-

00 * i * 1 / 1i * f

Development of the image areas, but also strengthens the field

over the background areas so that these areas are now toner of the wearer and dull the background areas of the image.

As far as the arrangement has been described so far, this is in itself known. So far, attempts have been made to avoid the difficulties that arise by connecting the development electrode an external voltage source, and complicated control circuits had to be provided in order to raise the potential of the development electrode set such a value as to ensure satisfactory development of the images.

In the embodiment according to FIG. 1, the cylinder 19 is over an electrical impedance, which in this case consists of the line 34 and the resistor 35. This circuit delays the discharge of charge from cylinder 19 and causes the cylinder assumes a potential with respect to earth as long as an electrostatic image is developed. However, this allows Circuit to drain part of the charge so that the cylinder 19 assumes a potential which is lower than that which it

i would assume if the cylinder 19 was from its surroundings

would be electrically isolated. The resistance is chosen so that LE 9-69-013 -8-

009841/1 (35

BATH ORIGINAL

the potential is just emerging »which the desired suppression causes the clouding of the background areas. The size of the resistor used depends on the potential of the photo conductor and can easily be determined empirically.

The arrangement was experimentally used to create latent charge images to develop on the photoconductive layer 13, which corresponded both line art and halftone originals and Mixtures of both types, and where the resistance was changed from infinity to earth fault. When the resistance was infinite was., i.e. the development electrode on a floating

the potential was a negative voltage of about 600 '. 750 Volts measured at the development electrode and practically at all no image could be developed on the photoconductor by toner particles. If by removing the resistor the electrode was grounded directly, the image was fully developed, however, the background areas became very dark. In the following Table I values are entered for the development electrode

measured induced voltages when the resistance of V

8 8

about 1 x 10 6 up to 10 x 10 7 ohms was varied.

LE9-69-013 -9-. "

. ■ -... ■ - 009841/1635

BATH

TABLE I.

Resistance (ohm)

Induced voltage on cylinder 19 (volts)

Grounded

χ 10

2.0. χ IQ 3.33 χ 10

10.0 10

100. 300

125-425

350-550

450-600

600-750

Au · the data in Table I it can be seen that the voltage on the cylinder 19 increases when the value of resistance is increased. The voltage varied by about 200 volts because the total charge - of the areas on the photoconductive layer 13, which passed the cylinder 19, varied according to the ratio of the charged areas and the discharged areas of the charge image. As the voltage on the electrode increased, they showed

ο
Images show a progressive drop in the background until at

8th
3.33 χ 10 ohms a loss in the degree of filling was observed,

ο
which became even more striking at the value 10 χ 10 ohms. · The

Resistance with the value 2.0 χ 10 Ohm gave the best grain

IV 9..60-013

-10-

009841/1635 BATHROOM ΟΡ «Ν & Γ

combination of a good degree of filling of the image areas and background suppression.

The voltage B fluctuations observed at each resistance value of about 200 volts did not appear to affect overall image quality except when heavily opaque images and line copies were to be developed side by side. In these cases caused a by walking past large charged surfaces the electrode caused a sudden increase in voltage a tendency to underdevelop the line copy., This effect can be are compensated by damping the voltage fluctuation according to the embodiment of FIG. 2. The cylinder a magnetic brush developing device is over a resistor 43 grounded. A capacitor 45 is connected in parallel with resistor 43. The appropriate values for the Resistance and capacitor can easily be determined empirically, depending on the nature of the images to be developed. By caused the inducing differently charged image parts Voltage fluctuations in the cylinder 41 have been reduced by the capacitor, which attenuated the sharp voltage spikes that

Ί.

otherwise observed using the resistor alone.

■ _ - ■ yy. . - - = ■

The total voltage fluctuations were estimated to be around 100 volts for

the same copy template is reduced, which when using the LE 9-69-013 -11-

009841 / 1S35

" BATH ·

It

Resistance alone caused fluctuations of about 200 volts. For example, connecting a capacitor in parallel resulted in 45

from O.OlyuFarad with a resistance 43 of 6.0 χ 10 ohms

Image with an excellent degree of filling and unobservable clouding of the background.

For better adaptability of the operation , the impedance can be made adjustable for the operator, for example by an adjustable resistor which can be set to an experience value, depending on the type of image that is to be developed.

LE 9 '-013 -12-

00984.1 / 1635

Claims (5)

PATENT CLAIMS rl.j developing electrode in an electrophotographic copier, which is arranged in the vicinity of the photoconductive layer, and which, through their charging, the transfer of toner particles to the photoconductive layer supports the development of latent charge images, characterized in that the electrode (19) is on a floating Potential designed to be self-charging and via an impedance (35, 43, 45) is grounded. jflj 2. Development electrode according to claim 1, characterized in that the impedance is a resistor (35). 3. Development electrode according to claim 1, characterized in that the impedance the parallel connection of a resistor (43) with a Capacitor (45) is. ' 4. developing electrode according to claim 1, characterized in that the impedance is adjustable. 5. Development electrode according to claim 1, characterized in that the electrode of the metallic base body (15) of a magnetic Brush is. ORIGINAL B | im? EC! TEa M Blank page