DE3243705C1 - Method and device for electrophotographic imaging - Google Patents

Description

The invention relates to a method for electrophotographic imaging in which on a photoconductive Intermediate image carrier generates an electrostatic latent image, one for developing this latent image with a rotating magnetic brush working with a non-magnetizable sleeve surrounding the magnetic core an insulating, magnetic one-component toner is used while the intermediate image carrier is being passed leaving a distance on the one from one with respect to the intermediate image carrier high-frequency alternating voltage with a direct voltage level existing bias voltage lying Magnetic brush toner deposited on the image areas of the intermediate image carrier and finally the resulting Toner image is transferred from the intermediate image carrier to a receiver sheet and fixed there.

From US-PS 41 21 931 a method for electrophotographic image generation is known, where 'with-. a means of a metering defining Abstreifeinrich- ^c tung the thickness of the toner coating on the rotating sleeve predetermined and for the purpose of charging of the toner between the intermediate image carrier and the sleeve and / or the stripping means, a DC voltage is applied. .

The main disadvantage of the known method is that that the development of fine lines is difficult and spreads everywhere due to the polarizability of the toner There is toner settling where there is a difference between the potential of the charge image and the development electrode exists, so that there is always the risk of a disturbing background formation.

From US-PS 42 99 900 is a development process for magnetic, insulating one-component toner known, with a toner layer thickness being used on the magnetic brush that is smaller than the developing .. lungs gap. While the sleeve of the magnetic brush is rolling- "

rend, a vertically arranged magnetic core is used, so that the adjustment of the toner layer thickness on the magnetic brush by means of a magnetic scraper can take place opposite a standing pole. Of the

Toner is triboelectrically charged. According to one embodiment This known method can be between the intermediate image carrier and the magnetic brush Low-frequency alternating voltage are applied, the frequency of which is 200 Hz and the voltage of 800 V ^ amounts to.

The disadvantage of this known method is especially "the use of a very thin layer of toner on the magnetic brush, the resulting Toleranzforde- • wrestled and as a result of the difficult production, in - prerequisite for a valid work is namely that between the toner layer thickness and the Development gap a very precise relationship is maintained and it is required that the development gap is less than or equal to 0.3 mm.

From US-PS 38 93 418, which describes a process also referred to as a "jumping method", it is known for loosening the toner particles of a microfield toner brush with non-magnetic one-component toner Apply high-frequency square pulses between the toner brush and the intermediate image carrier. Around on the one hand, an improvement in the line copies and, on the other hand, an improvement in the halftone area to achieve is a combination of two high frequency pulse trains with frequencies from 2 to 5 kHz and 18 to 22 kHz used.

The disadvantage here is the complicated and also expensive structure for the microfield clay brush, since it is a non-magnetic one Toner must be used. Overall, the result is a complex apparatus that also looks good the susceptibility to failure is critical.

From DE-OS 31 02 600 a development process for magnetic latent images is known that with a changing electric alternating field works in the development gap. This alternating electric field is even in the places where there is no magnetic latent image, so large that the toner particles always cross the development gap so that the toner particles adhere to the non-image as well as to the a magnetic image having locations of the latent image carrier are transferred, whereby the image-free Make a background veil builds up. The retransfer of the toner particles forming this background fog is to be brought about by the part of the applied alternating voltage which is in phase opposition.

However, due to the forces acting in the near area, the toner particles forming the background haze are removed so strongly bound to the surface of the latent image carrier that retransfer is incomplete he follows. If these retained toner particles are transferred to a receiver sheet, then the Copy is a background that degrades copy quality. There is no transfer of the toner particles the receiver sheet, they must be removed from the latent image carrier by means of a cleaning process, what to an undesirable increase in the economic efficiency of the copying process Toner consumption per copy leads or requires a complex return device, which in turn eliminates the problem brings about a change in the composition of the toner supply.

The object of the invention is to provide the method of the type defined at the beginning using an insulating, magnetic one-component toner, with fine, in particular diameters in the range from 5 to 15 micron-sized toner particles in such a way that during the development of the charge image a narrowing of thin lines as well as a toner transfer to the non-image areas of the intermediate image carrier is prevented, so that any toner return is superfluous and at the same time a good area coverage, a clean background and good edge sharpness is guaranteed.

This object is achieved according to the invention in that the amplitude and the frequency of this Preload be dimensioned so that by the interaction of the alternating magnetic field with The alternating electric field is limited in its dimensions and consists of vibrating particles Toner cloud is formed, the thickness of which in the radial direction is smaller than the distance between the intermediate image carrier and magnetic brush and that the transport of the toner particles only to the image areas at least essentially through that originating from the charge image on the intermediate image carrier electrostatic field is caused.

The measures provided according to the invention lead to surprisingly advantageous copying results resulting interaction of electrical and magnetic forces.

That extends along the circumference of the mantle and also in the development gap The forming alternating magnetic field generates together with the likewise the mobility the high-frequency alternating voltage on the magnetic brush, which increases the inherently poorly flowing toner particles a cloud defined in terms of its extent by the specifically selected vibration amplitudes in highest excitation particles. Out of this cloud, the development gap is extremely flexible However, non-traversing particles can be caused by the electrostatic forces exerted by the charge image carrier originate from the intermediate image carrier, possibly supported by triboelectric charging of the toner particles, the toner particles required for developing the charge image are removed and placed on the intermediate image carrier be deposited.

Since, on the one hand, the toner particles do not cross the development gap in the non-image areas, on the other hand but the small electrostatic forces resulting from fine charge image lines are sufficient to Transferring toner particles to the intermediate image carrier in a very defined manner can be both thin Lines flawless, d. H. developed without narrowing as well as disturbing background effects in the non-image Areas are switched off, so that no toner return is necessary.

The magnetic core and one surrounding it and carrying the toner particles are preferred conductive and non-magnetizable sleeve driven in opposite directions.

An advantageous device for carrying out the method consists of a toner storage container associated, consisting of a multi-pole magnetic core and a sleeve magnetic brush, a one Squeegee defining the metering gap, an intermediate image carrier carrying a photoconductor layer, which together with the magnetic brush defines a development gap, as well as a generator for generating a DC voltage superimposed high frequency voltage used as bias, and this device excels characterized in that the metering gap established by the metering blade is about half as large as the development gap between the magnetic brush and the photoconductor layer of the intermediate image carrier and that the magnetic core is connected to a rotary drive.

Further advantageous embodiments of this device are listed in subclaims ..

Essential in connection with all embodiments of a device for performing the Method is that the critical parameters are not mechanical, but electrical, and the electrical parameters can be specified very precisely without any special effort, resulting in a From a manufacturing point of view, the overall arrangement is particularly favorable and also extremely reliable.

Exemplary embodiments of the invention are described below, for example, with reference to the drawing explained; shows in the drawing

F i g. 1 shows a schematic representation of a first embodiment a device for performing the method according to the invention, and

F i g. 2 is a likewise schematic representation of a another variant.

According to Fig. 1, an insulating, magnetic one-component toner 2 is contained in a storage container 1, the specific resistance of which is at least 10 ¹³ ßcm.

The particles of this one-component toner in particular have dimensions in the range from 5 to 15 microns.

In the outlet area of the storage container 1 is a Mag- 'marked with the general reference number 3 net brush arranged, which consists of a multi-pole magnetic core 4 and an electrically conductive, non-magnetizable Sleeve 5 consists, which preferably has an insulating coating with a layer thickness in the range of may be about 2 to 20 microns.

In the illustrated embodiment, the magnetic core 4 is clockwise and the sleeve 5 is counterclockwise driven.

During operation, a layer of toner particles is formed on the sleeve 5, the thickness of which is determined by the metering blade 6, which consists in particular of iron or brass, is specified.

A generator 7 generates a high-frequency alternating voltage superimposed on a direct voltage, which is applied to the magnetic brush, or is applied to the sleeve 5.

The intermediate image carrier is made up of a photoconductor layer 9 formed, which is mounted on a drum 8, which is in the illustrated embodiment in Moved counterclockwise.

A development gap rf is set between the photoconductor layer 9 and the magnetic brush 3, which is preferably approximately twice as large as the metering gap d ₂ selected between the magnetic brush and the doctor blade 6 .

The operating parameters for the device described are preferably selected as follows:

Speed of sleeve 5:
Direction of rotation sleeve 5:
Outer diameter sleeve 5
Speed core 4:
Direction of rotation core 4:
Diameter core 4:
Magnet:

Development gap:
Dosing gap:

AC voltage:

DC voltage:
Photoconductor 9:

Photoconductor speed:
Direction of rotation photoconductor:

80 rpm.

Counterclockwise: 32.2 mm

700 rpm.

Clock hands

29.5 mm

lO-pole, 650 Gauss

measured on the sleeve,

rf, = 0.4 mm

d ₂ = 0.25 mm, metering squeegee

made of iron
/ = 10 kHz,

U = 1500 Vpp, sinusoidal

U = +60 V

selenium

ν = 12 cm / sec.

Counterclockwise.

With a device of this type and the specified parameters, flawless copies with good area coverage, clean background, good edge definition and without narrowing of the thin lines.

The variant embodiment according to FIG. 2 differs from the device explained with reference to FIG. 2 through the opposite directions of rotation of core 4 and sleeve 5 in different parameters.

The parameters were for the device according to FIG chosen as follows:

71.5 rpm.

Clock hands

900 rpm.

Counterclockwise

lO-pole, 650 Gauss

measured on the sleeve

Ct ₁ = 0.4 mm

d ₂ = 0.2 mm, metering squeegee

made of brass

/ = 6kHz, i / = 1400 Vpp,

Speed of sleeve S:
Direction of rotation sleeve 5:
Speed core 4:
Direction of rotation core 4:
Magnet:

Development gap:
Dosing gap:

AC voltage:

DC voltage:

Photoconductor 9:

Photoconductor speed:

Direction of rotation photoconductor:

This embodiment variant also produced perfect copies for the purposes of the present invention achieved.

sinusoidal

U = + 60 V

selenium

ν = 12 cm / sec.

Counterclockwise.

For this purpose 2 sheets of drawings

Claims (13)

Patent claims: 1. Electrophotographic imaging method; in the case of an electrostatic latent image on an intermediate photoconductive image carrier generated, for the development of this latent image, one with a rotating one, with a non-magnetizable one Magnetic brush that surrounds the sleeve and is made from an insulating, magnetic one-component toner used while passing the intermediate image carrier while leaving a distance on the one with respect to the intermediate image carrier on one of a high-frequency alternating voltage A DC voltage level bias magnetic brush toner on the image areas of the intermediate image carrier and finally the toner image obtained from the intermediate image carrier is transferred to a recipient sheet and fixed there, characterized in that that the amplitude and the frequency of this bias voltage are dimensioned so that by the interaction of the alternating magnetic field with the alternating electric field one in its dimensions limited, consisting of vibrating particles toner cloud is formed, the thickness of which in radial Direction is smaller than the distance between the intermediate image carrier and the magnetic brush and that the exclusively Transport of the toner particles to the image areas at least essentially through the electrostatic field originating from the charge image on the intermediate image carrier is brought about. 2. The method according to claim 1, characterized in that the magnetic core and a surrounding it, the electrically conductive and non-magnetizable sleeve carrying the toner particles is driven in opposite directions will. 3. Apparatus for performing the method according to claim 1 or 2, consisting of a one Allocated toner storage container, consisting of a multi-pole magnetic core and a sleeve Magnetic brush, a squeegee defining a metering gap, an intermediate image carrier carrying a photoconductor layer, which, together with the magnetic brush, defines a development gap, as well as a gene- 45 rator for generating a high-frequency voltage superimposed on a direct voltage and used as a bias voltage, characterized in that the metering gap (d ₂ ) established by the metering doctor blade (6) is about half as large as the development gap CiZ ₁ ) between the magnetic brush (3) and the photoconductor layer (9) of the intermediate image carrier, and that the magnet core (4) is connected to a rotary drive. 4. Apparatus according to claim 3, characterized in that that the magnetic core has at least eight poles ^ of alternating polarity. 5. Apparatus according to claim 3, characterized in that the magnetic core (4) enclosing conductive sleeve (5) is provided with an insulating coating. · 6. Apparatus according to claim 5, characterized in that the layer thickness of the coating in Range from about 2 to 20 microns. 7. Apparatus according to claim 3, characterized in that the metering doctor (6) made of magnetizable or magnetic material. 8. Apparatus according to claim 3, characterized in that the metering doctor (6) made of non-magnetic Material consists. 9. Apparatus according to claim 3, characterized in that that the frequency of the alternating voltage is in the range of about 5 to 12 kHz. 10. The device according to claim 3, characterized in that the DC voltage level is less than 100 V is. 11. The device according to claim 3, characterized in that the DC voltage level is in the range from 20 V to 80 V and in particular about 60 V. 12. The device according to claim 9, characterized in that the high-frequency alternating voltage is at least essentially sinusoidal and superimposed on the DC voltage, 13. The apparatus according to claim 12, characterized in that "the peak-to-peak value of the high frequency AC voltage is greater than 1000 V.