DE19942116A1 - Corotron device for transfer unit in electrographic printer, copier, with attraction between intermediate carrier and opposing electrode decreased by opposing electrode having raised portions - Google Patents

Abstract

Transfer corotron unit (46) has corotron wire (12) and opposing electrode in form of blade (14) with point or raised sections in form of pins. Photoconducting belts (16a,16b) and paper path (48) are fed between the corotron wire and blade without contacting them. Corotron wire has positive potential and blade has negative potential. Transfer corotron unit (46) has corotron wire (12) and opposing electrode in form of blade (14), or raised sections in form of pins. Photoconducting belts (16a,16b) and paper path (48) are fed between the corotron wire and blade without contacting them. Corotron wire has positive potential and blade has negative potential. Positive charged toner particles (20) of latent image (18a) are repelled by corotron wire and attracted by negative charged toner particles (22) of latent toner image (18b) and blade. Negative charged toner particles (22) of image (18b) are repelled by blade and attracted by toner particles(20), image (18a) and wire.

Description

The invention relates to a corotron device for electro graphic printing and / or copying devices, with at least one corotron wire with a first poten tial, with at least one counter electrode with one of the er most potential different second potential and with min at least one between the corotron wire and the counter electrode intermediate carrier for toner images.

For printing on a final image carrier, e.g. B. paper, is a Transfer of a toner image on an intermediate carrier of the final image carrier mechanically, thermodynamically or made electrostatically. For an electrostatic Transfer the toner image from a photoconductor belt to one The toner must be on the intermediate carrier or on a final image carrier particles have a certain potential for tension. The elec Trostatic transfer of the toner particles takes place through forces in the electric field and is based on a potential difference between the toner particles and the final image carrier on which the toner image is to be transferred. The power through that electrical field must be greater than the binding forces by which the toner particles on the intermediate carrier for Toner images from which they are to be transferred are held the.

In electrographic printing and / or copying facilities who the dry toner particles for electrographic transfer a suitable voltage potential, so that the Transfer the toner particles to a material without additional Influencing the charge of the toner particles in the printer or copy rer can be performed. Should the final image carrier be on the sides are printed (duplex printing), the final image must ger be turned, or there is a simultaneous or time-delayed transfer of the toner particles from both sides  on the final image carrier. To transfer without intermediate fixation of the toner image transferred to the final image carrier the toner particles on the first page of the Intermediate carrier to the toner particles of the second side Show potential difference. Preferably the toners particles from a positive voltage potential to a ne negative voltage potential, in relation to the ground potential, reloaded. Thus, the toner particles can be simultaneously or staggered in time without intermediate fixation of the intermediate carrier be transferred to the final image carrier from both sides. Pull the toner particles on both sides of the final image carrier themselves through their different potentials through the end through and / or through the potential difference to the final image carrier, so that they are on the Final image carriers stick.

After the transfer process, toner particles remain attached to the intermediate carrier from which they are to be transferred, ie they have not been successfully transferred. These are toner particles of a few percent of the toner image, usually considerably less than 20 percent. These untransferred toner particles usually have a low or incorrect voltage potential. For a further transfer the water not transferred toner particles, for. B. for cleaning the intermediate carrier to perform with a high efficiency, it is necessary to charge the toner particles to a defined potential. This loading process takes place with a Ko rotroneinrichtung. The intermediate carrier forms the Ge counterelectrode to the corotron device. If the intermediate carrier is a conductive material with a specific resistance of less than 10 ⁶ ohm cm, the intermediate carrier is connected to ground potential or to another suitable voltage potential and thus serves as a counter electrode. Is the intermediate carrier z. B. in the case of a photo conductor provided with a light-sensitive cover layer, the dark resistance of which is very high-impedance (for example greater than 10 ⁶ ohm cm), a counter electrode must be arranged on the back of the intermediate carrier. Counter electrodes are preferably performed as metal plates or as conductive deflection rollers. Since deflection rollers are associated with a high mechanical outlay, increased space requirements and high costs, primarily metal plates are used as counter electrodes.

The counter electrode should have a low contact resistance own the intermediate carrier. The intermediate carrier is on the fixed counter electrode passed without contact. Around To achieve the low contact resistance, the Zwi Braces at a short distance on the fixed counter lead electrode. This distance is before preferably 0.2 mm to 1.0 mm. The forces between two bodies pern, due to their potential difference, an electric field is generated with the forces between two plates Nes plate capacitor comparable, with a plate of the Plate capacitor through the counter electrode and the other Plate formed by the underside of the intermediate carrier becomes. A force in Rich then acts on the intermediate beam device of the fixed counter electrode. This force leads to the fact that the band-shaped intermediate carrier on the counter elec trode deflects in their direction, touches and adheres to it tet. Through the contact between the moving band-shaped Intermediate carrier and the fixed counter electrode is created Static and sliding friction. The in addition to the drive of the Zwi due to this friction between the intermediate carrier and counterelectrode required mechanical energy from the Drive unit of the intermediate carrier are applied. Au In addition, due to the sliding friction, the intermediate carrier and / or the counter electrode is worn.  

In WO 87/02792 a corotron device with a Ko rotron electrode described, the counter electrode as metal plate is executed. This metal plate lies on the ground potential. That between the corotron electrode and the counter Electrode generated electric field leads to a charge influence of the toner particles.

The object of the invention is to provide a corotron device give between the intermediate carrier for toner images and the counterelectrode have low attractive forces and the load carrier exchange is guaranteed.

The object is solved by the features of claim 1. Advantageous embodiments of the invention are shown in the pending claims specified.

According to the invention, the counter electrode has a conductive elevation gene whose end points protrude in the direction of the corotron wire and that in a plane parallel to the longitudinal axis of the Koro trondrahtes lie. By designing the counter electrode is achieved that the attraction between the intermediate carrier and the counter electrode is significantly reduced. This Attraction depends crucially on the effective area from. The decisive effective area is that of the intermediate beam facing surface of the counter electrode. By arranging electrically conductive surveys, the end points of which are the represent effective area, it is guaranteed that the effective area and thus also the attractive forces between the intermediate carrier and the counter electrode are small. By this arrangement is also achieved by the curvatures at the surveys there is an increased exchange of La manure carriers comes as a result of peak discharge.

A preferred embodiment of the invention provides that the bumps of the counter electrode along the longitudinal axis of the Corotron wire are arranged. This ensures that  the electric field to influence the charge on the toner particles formed evenly and the arrangement of the Ge space saving is possible.

Another embodiment of the invention is thereby ge indicates that the counter electrode as elevations single contains pens. This ensures that the counter electrode who are inexpensive to manufacture from standardized components that can.

Another preferred embodiment of the invention be is that the counter electrode tapered protrusion gene contains. This ensures that the effective area the counter electrode and thus the force of attraction between the Intermediate carrier for toner images and counter electrode is discontinued.

According to a further aspect of the invention is a Koro tron device for an electrographic printing and / or Ko piereinrichtung provided that the counter electrode according to Art a blade with a cutting edge is formed, the Cut parallel to the longitudinal axis of the corotron wire is arranged. This configuration ensures that, for. B. a sheet metal plate that is perpendicular to the intermediate carrier for toner pictures is arranged and across the width of the intermediate carrier for toner images, is used as a counter electrode. Such an arrangement is space-saving and inexpensive. This arrangement also ensures that it is Curvatures on the cutting edge for an independent exchange from charge carriers (to a peak discharge).

Another cheap design of the Korotroneinrich tion provides that the cutting edge of the counter electrode is serrated is and that the prongs are in the direction of the corotron wire taper so that the end points and / or end faces of the Zac project in the direction of the corotron wire and parallel to the  Longitudinal axis of the corotron wire. This ensures that the effective area from which the amount of attraction force between the intermediate carrier for toner images and counter electrode is dependent on the continuous blade is reduced, which further reduces the attraction is gert. The peak discharge is further favored.

According to a further aspect of the invention is a Koro tron device for an electrographic printing and / or Ko piereinrichtung provided that the counter electrode by egg NEN wire is formed, the longitudinal axis parallel to Longitudinal axis of the corotron wire is arranged. With this Design is achieved that z. B. also a corotron wire is arranged as a counter electrode. This wire runs across the width of the intermediate beam. Such an arrangement is space-saving and reduces the number of construction used parts.

Further features and advantages of the invention result from the following description, which in connection with the at attached drawings, the invention based on exemplary embodiments play explained.

Show it:

Fig. 1 a Umladekorotroneinrichtung wires with two corotron and formed with two blades as the counter electrode,

Fig. 2 is a Umladekorotron with a corotron wire and blade ei ner used as a counter electrode, wherein the Feldli nien are indicated of the effective electric field,

Fig. 3 is an illustration of a counter electrode which is designed as a blade,

Fig. 4 shows the view of a blade, wherein the blade is serrated,

Fig. 5 illustrates a counter electrode, which consists of an array of individual pins,

Fig. 6 shows a counter electrode consisting of a wire, and

Fig. 7 is a Umdruckkorotroneinrichtung with a Koro trond wire and with a trained as a blade Gegenelek electrode.

In Fig. 1, a Umladekorotroneinrichtung 10 is shown with two Ko rotron wires 12 and with two blades Ge formed as electrodes 14 . A fo toleiterband 16 is provided as an intermediate carrier. However, a transfer belt can also be used.

The photoconductor belt 16 with an as yet unfixed toner image 18 , which contains positively charged toner particles 20 or, after recharge, negatively charged toner particles 22 , is carried out between the two corotron wires 12 and the two counterelectrodes 14 , being guided by deflection rollers 24 and is driven. The blades 14 are attached to a bracket 26 which also provides the electrical connection to the ground potential of the printing and / or copying device 28 . The corotron wires 12 are surrounded by two screens 30 on the side facing away from the photoconductor tape 16 . The photoconductor band 16 is guided past the counter electrodes 14 at a distance in the range from 0.2 mm to 4 mm, preferably in the range from 0.2 mm to 1 mm. The negatively charged toner particles 22 of the latent toner image 18 are reloaded by the electric field between the corotron wires 12 and the counter electrodes 14 .

FIG. 2 shows a recharging corotron device 10 with a corotron wire 12 and a single blade used as counter electrode 14 , the field lines 32 , 34 of the effective electric field being indicated. The effective area, on which the amount of attraction between the photo conductor tape 16 and the counter electrode 14 is dependent, is denoted by 36 . The counter electrode 14 has ground potential. Alternatively, the counter electrode can have a negative potential with respect to the ground potential. An electrical field is formed between the corotron wire 12 and the counter electrode 14 . This field 34 acts on the toner particles 22 , which have negative potential. The toner particles 22 are discharged as they pass the corotron wire 12 and charged to a positive potential. The amount of the potential of the now positively charged toner 20 depends on the dwell time of the toner in the electric field and on the density of the electric field. The photoconductor tape 16 is attracted to the counter electrode 14 . The attraction F is determined from the relationship:

where ε _r the dielectric constant of the air between the photo conductor tape 16 and counter electrode 14 , A the effective area 36 of the counter electrode 14 in the electric field, U the potential difference and d the distance between the underside of the photo conductor tape 16 and the counter electrode 14 .

In Fig. 3, a further counter electrode 14 is shown, which is designed as a blade. This blade 14 has a rectangular cross section and is fastened by a holder 26 in the printer and / or copier 28 .

In Fig. 4, a blade 14 is shown, the cutting edge is serrated. The blade 14 is arranged in the printer / copier 28 so that the teeth 40 taper towards the photoconductor belt 16 . The teeth 40 are arranged at equal intervals. This arrangement ensures a uniform charge of the latent toner image 18 . The holder 26 of the blade 14 is not shown in this figure.

In FIG. 5, a counter electrode 14 is shown, which consists of an array of individual pins 42. The pins 42 are net angeord on a holder 26 at symmetrical intervals. The holder 26 is arranged in the printer and / or copier 28 so that the ends of the individual pins 42 lie in a parallel plane to the photoconductor tape 16 or to the corotron wire 12 , and parallel to the corotron wire.

In FIG. 6, a counter electrode 14 is shown, which consists of a wire 44. The wire 44 is arranged by a suitable holding device 26 in the printer and / or copier 28 so that it band 16 in a parallel plane to the photoconductor and parallel to the corotron wire 12 . A screen 30 is arranged on the side of the wire 44 facing away from the photoconductor tape 16 . As a wire 44 is a Koro trondraht 12 similar wire 44 is used.

FIG. 7 shows a transfer printing corotron device 46 with a corotron wire 12 and with a counter electrode 14 designed as a blade 14 . Two photoconductor tapes 16 a and 16 b are provided as intermediate carriers. Alternatively, two transfer belts can also be used. A not yet fixed toner image 18 a on the photoconductor belt 16 a contains positively charged toner particles 20 . A not yet fi xed toner image 18 b on the photoconductor belt 16 b contains negatively charged toner particles 22 . The photoconductor tapes 16 a and 16 b and a paper web 48 are guided between the coro wire 12 and the blade 14 without touching them, the photoconductor tapes 16 a, 16 b being guided and driven by deflection rollers 24 . The drive and the guide of the paper web 48 is not shown in this figure. The corotone wire 12 has a positive potential and the blade 14 has a negative potential with respect to the ground potential. The corotron wire 12 is surrounded on the side facing away from the photoconductor tape 16 a by a screen 30 . The positively charged toner particles 20 of the latent toner image 18 a are repelled by the positively charged corotron wire 12 and are attracted by the negatively charged toner particles 22 of the latent to ner image 18 b and by the negatively charged blade 14 . Analogously, the negatively charged toner particles 22 of the latent toner image 18 b are repelled by the negatively charged blade 14 and attracted by the positively charged toner particles 20 of the latent toner image 18 a and by the positively charged corotron wire 12 . On the positively and ne gativ charged toner particles 20 , 22 acts by the transfer corotron 46, a force that is greater than the binding forces between the toner particles 20 , 22 and the photoconductor belts 16 a, 16 b. The positively and negatively charged toner particles 20 , 22 are printed onto the paper web 46 by the field forces of the electrical field. On the paper web 46 , the toner particles 20 , 22 remain adhered by the binding forces between the toner particles 20 , 22 and the paper web 46 and by the attraction between the positively charged toner particles 20 on one side of the paper and the negatively charged toner particles 22 on the other side of the paper.

Reference list

10th

Transshipment corotron facility

12th

Corotron wire

14

Counter electrode

16

Photoconductor tape

18th

latent toner image

20th

positively charged toner particles

22

negatively charged toner particles

24th

Deflection roller

26

holder

28

Printing and / or copying device

30th

umbrella

32

Field lines

34

Field lines

36

effective area of the counter electrode in the electric field

40

Pink

42

Single pens

44

wire

46

Transfer corotron

48

Paper web

Claims (16)

1. corotron device ( 10 ) for an electrographic printing and / or copying device ( 28 ),
with at least one corotron wire ( 12 ) with a first potential,
with at least one counter electrode ( 14 ) with a second potential different from the first potential,
and with at least one intermediate carrier ( 16 ) for toon images between corotron wire ( 12 ) and counter electrode ( 14 ),
characterized in that
the counter electrode ( 14 ) has electrically conductive elevations ( 40 , 42 ), the end points of which project in the direction of the corotron wire ( 12 ) and which lie in a plane parallel to the longitudinal axis of the corotron wire ( 12 ) and parallel to the intermediate carrier ( 16 ). 2. Corotron device ( 10 ) according to claim 1, characterized in that these elevations ( 40 , 42 ) run parallel to the longitudinal axis of the corotron wire ( 12 ). 3. Corotron device ( 10 ) according to one of the preceding claims, characterized in that the counterelectrode ( 14 ) contains individual pins ( 42 ) as elevations. 4. Corotron device ( 10 ) according to one of the preceding claims, characterized in that the counter electrode ( 14 ) contains tapered elevations ( 40 , 42 ). 5. Corotron device ( 10 ) for an electrographic printing and / or copying device ( 28 ),
with at least one corotron wire ( 12 ) with a first potential,
with at least one counter electrode ( 14 ) with a second potential different from the first potential,
and with at least one intermediate carrier ( 16 ) for toon images between corotron wire ( 12 ) and counter electrode ( 14 ),
characterized in that
the counter electrode ( 14 ) is designed in the manner of a blade with a cutting edge, the cutting edge being arranged parallel to the longitudinal axis of the corotron wire ( 12 ). 6. Corotron device ( 10 ) according to claim 5, characterized in that the cutting edge is serrated and that the end points and / or end faces of the serrations ( 40 ) protrude in the direction of the corotron wire ( 12 ) and parallel to the longitudinal axis of the corotron wire ( 12 ) lie. 7. corotron device ( 10 ) according to claim 6, characterized in that the prongs ( 40 ) in the direction of the Koro trond wire ( 12 ) taper. 6. Corotron device ( 10 ) according to one of the preceding claims, characterized in that the cross section of the blade ( 14 ) tapers in the direction of the corotron wire ( 12 ). 9. Corotron device ( 10 ) according to one of the preceding claims, characterized in that the cutting edge has a width which is in the range from 0.02 mm to 0.5 mm, preferably in the range from 0.02 mm to 0.1 mm lies. 10. Corotron device ( 10 ) for an electrographic printing and / or copying device ( 28 ),
with at least one corotron wire ( 12 ) with a first potential,
with at least one counter electrode ( 14 ) with a second potential different from the first potential,
and with at least one intermediate carrier ( 16 ) for toon images between corotron wire ( 12 ) and counter electrode ( 14 ),
characterized in that
the counter electrode ( 14 ) is designed as a wire ( 44 ),
wherein the longitudinal axis of the wire ( 44 ) is arranged parallel to the longitudinal axis of the corotron wire ( 12 ). 11. Corotron device ( 10 ) according to one of the preceding claims 1 to 10, characterized in that the Koro trond wire ( 12 ) and the counter electrode ( 14 ) lie in a plane which is perpendicular to the intermediate carrier ( 16 ). 12. Corotron device ( 10 ) according to one of the preceding claims, characterized in that the intermediate carrier ( 16 ) is a photoconductor belt or a transfer belt. 13. Corotron device ( 10 ) according to one of the preceding claims, characterized in that the Korotronein direction ( 10 ) is a transfer corotron, a charging corotron, a transfer printing corotron or an extinguishing corotron. 14. Corotron device ( 10 ) according to one of the preceding claims, characterized in that the intermediate carrier ( 16 ) at a distance in a range from 0.2 mm to 4 mm, preferably in a range from 0.2 mm to 1 mm the counter electrode ( 14 ) is passed. 15. Corotron device ( 10 ) according to any one of the preceding claims, characterized in that the counter electrode ( 14 ) has ground potential. 16. Corotron device ( 10 ) according to any one of the preceding claims, characterized in that the intermediate carrier ( 16 ) consists of a high-resistance material which has a specific resistance of <10 ⁶ ohm cm.