DE2055992A1 - Electrode arrangement with image material supply - Google Patents

Description

Patent attorneys Dipl.-Ing. F. Weickmann, 2055992

Dipi.-Ing. H. Weicxmann, Bipl.-Phys. Dr.K. Fincke D1PL.-ING. R A.WEICKMANN, Dipl.-Chem. B. Huber

S MUNICH 86, POST BOX 160 «20

MÖHLSTRASSE 22, CALL NUMBER 48 3921/22

<983921/22>

XEROX CORPORATION, Xerox Square, Rochester, N.Y. 14603,

Electrode arrangement with image material supply

The invention relates to an electrode arrangement with Image material supply, especially for one after the fotoelectrophoretisctosn Imaging process working copier.

U.S. Patents 3,384,488, 3,384,566, and 3,383,993 teach a photoelectrophoretic imaging process known for producing black and white or colored images. In this process, photoelectrophoretic migrations Particles in an image-wise distribution on one or both of two electrodes, between which the particles are in one Image suspension are located. The particles are sensitive to light and obviously undergo a change in their charge polarity when interacting with one of the two Electrodes when hit by electromagnetic radiation that activates them. Ee are therefore no further light-sensitive elements or substances required, so that a simple and cheap imaging process results. Mixtures of two or more different colored Types of particles enable the production of multicolored images. The particles of these mixtures can become overlapping or separate spectral sensitivity

1098 22/1745 SAO original

bereiqhe have and ¹ are suitable for subtractive color processes. The particles migrate away from one of the electrodes under the influence of an electric field when they are struck by light energy of a wavelength to which the colored particles are photosensitive.

A copier machine suitable for continuously carrying out this imaging process is e.g. from the US patent 3,427,242 known Furthermore, a copying machine has already been proposed which makes true-color copies of originals and produces documents. In order to be able to produce a particularly good image with this copier, a or multiple picture electrodes with the injecting electrode cooperate under suitable conditions of the photoelectrophoretic imaging process, this interaction must be carried out automatically and precisely using suitable components

The object of the invention is to provide a new electrode arrangement for the one according to the photoelectrophoretic imaging process working copying machine to create required picture electrodes in a simple manner and automatically the image suspension required for an imaging process can be supplied so that it is on the surface of the picture electrode into the imaging zone and in contact with the counter electrode used there, known as the injecting electrode.

In the case of an electrode arrangement of the type mentioned at the outset, this object is achieved according to the invention by one in one Tank movably mounted picture electrode, which can be moved past a certain point, and through one of the surface the image electrode as it moves and before it is reached Feeding device that feeds the image material to the specific location

2/1746 BATH ORIGINAL

Forming by di§ arrangement d.§r Bildelektroäe in a tank with which they zone along the z _e B "the image ungs, a copying" mssehiii © fee.stimmte point is movable, can automatically in a simple manner in the tank Image suspension can be brought onto the surface of the image electrode with the aid of the feed device, which is preferably also arranged in the tank and in the immediate vicinity of the image electrode, while it is also moving relative to the tank in the direction of the specific point.

Me invention is illustrated using one in the drawing

th exemplary embodiment explained in detail:

Figol scheraatically a preferred embodiment of a photoelectrophoretic copier machine,

Pigo2 a plan view of the electrode arrangement according to the invention, which has partially broken away to reveal hidden parts,

3 is a sectional view taken along line 3-3 of FIG Fig «. 2,

Figo4 is a side view of the electrode assembly in which hidden parts shown in dashed lines; "sfnd,

5 shows a side view of the electrode arrangement from the other side, with hidden parts also being shown in dashed lines are shown, and

6 is a partially SchnittdarBtellung along the line 6-6 of Figo2 ₀

The invention is explained here using a preferred exemplary embodiment which, with further assemblies for automatic and continuous production of copies of an original to be reproduced

1U98 22

However, the invention is not limited to such an exemplary embodiment, but can also be carried out differently within the scope of the specified patent claims use other than the embodiment explained here ₀ So here ζ _β Β · different assemblies for the execution of certain punctures are given, however any comparable assembly can replace the assemblies explained here, as long as it fulfills an identical or similar puncture as the assemblies shown here

109822/1745

A detailed description of the fundamentals and the mode of operation of the photoelectrophoretic imaging process used in the automatic copier described here and the interaction of the little ropes contained in the image suspension to generate an image is contained in the patent specifications mentioned at the beginning The imaging process used by the copier works with electromagnetic radiation in an image-wise distribution! to which the individual photoelectrophoretic diseases of the suspension are sensitive to light ο The activating radiation and an electric field above the image suspension work together within the imaging zone between two electrodes. An electrode referred to as a "translucent, injecting electrode" is electrically biased in a positive manner ^{with respect to an "image electrode 11} which, with the image suspension between them, face each other in the imaging zone. The negatively charged particles in the suspension are therefore attracted to the positive injecting electrode.

The injecting electrode got this name because it was adopted will, during the imaging process, impose electrical charges on the activated photosensitive particles injected The term "photosensitive" here gives the Property of diving, according to their attraction to the injecting electrode to change its charge polarity and under the influence of the electric field after exposure with of activating electromagnetic radiation to migrate away from the electrode · The term "suspension" is intended to mean a System with fixed parts, distributed in a fixed, fluid

10 9822/17 AS-

liquid or gaseous medium. " The terms used in the here described embodiment of the invention the suspension has, as usual, in a! Präger liquid suspended solid particles ,, The term "picture electrode ¹¹ describes the electrode particles to the suspension between the injecting electrode covers and photosensitive when in contact with activated no sufficient charges to force their migration from the picture electrode surface. The "imaging zone" or the "imaging area" is the area between the two electrodes in which photoelectrophoretic particles occur »

The particles in the suspension are normally non-conductive unless they are exposed to activating radiation spectral sensitivity hit v / earth. The negative particles get in with the injecting electrode Contact or in their immediate vicinity and remain in this position under the influence of the electric field until they cope with to be exposed to an activating electromagnetic radiation »The particles' near the surface of the injecting Electrode are the particles that create the final image on it · V / ground the particles of an activating them If radiation hits, they become conductive and create an electrical bond between mobile charge carriers. The negative Charge carriers of these bonds depend on the positive injecting electrode and the positive charge carriers according to the picture electrode ouch. The negative charge carriers near the interface between the particle and the injecting electrode can cover the short distance between the particles and the electrode surface and leave particles with positive Remaining charge back. Due to this polarity change, the particles with the residual positive charge are removed from the positively charged surface of the injecting electrode and repelled from the negatively charged surface of the picture

109822/1745 bad original

electrode sucked in «by an activating radiation Particles hit at a certain wavelength to which they are photosensitive, d <, h. of such a wavelength which causes an electrical bond of charge carriers within the particles, move away from the injecting one Electrode on top of picture electrode and only leave behind those particles which do not have a sufficient amount of radiation for a change in polarity Wavelength were hit.

Are all the particles used, therefore, light-sensitive to a certain or another wavelength and the The arrangement is exposed to a light image of this wavelength so that it forms a positive image on the surface the injecting electrode by removing particles originally bound to its surface, with only the unexposed ones Areas particles remain © The polarities of the arrangement can be reversed; still finds A picture can be provided with suspensions originally having a positive or negative charge Particles are used. " : ■■

The image suspension can be one, two, three or more differently colored Contain types of particles that have different spectral sensitivities, »In the case of a single color Process can produce the particles of the suspension any color and also produce the spectral sensitivity is relatively unimportant as long as it is in "an area of the" with a conventional exposure light source generated light spectrum lies · In multi-colored processes, the particles can be selected so that particles of different Color also against different waves «. lengths are sensitive to light *

For photoelectrophoretic imaging are the following

109822/1745

Steps, even venn in the order that they require:

(1) the particles migrate toward the injecting electrode under the influence of the electric field; (2) Generation of charge carriers within the particles when they are hit by activating radiation? (3) Particle Deposition on odei * near the surface of the injecting electrode? (4) Occurrence of electrical bonding within the particles. the injecting electrode? (5) Charge exchange the particles with the injecting electrode? (6) electrophoretic Migration to the picture electrode; and (7) particle deposition on the image electrode, creating a positive Image remained on the injecting electrode

When generating the image on the injecting electrode, this can be in contact with the image transfer device are brought, which is opposite to the picture electrode has electrical charge polarity «. The injecting electrode will now become negative to the transmitter Pre-tensioned The particles with a negative residual charge are therefore attracted to the transmission device which is positive in relation to them When the carrier material is brought between the transfer device and the particle image, the particles reach the Backing materialο In this way it can be used on any backing material a photographically positive image can be created «.

1Q9822 / 174b

BATH ORIGINAL

In the copying machine shown in JFigc.1 injecting electrodeΊ a translucent cylinder jacket part, which is held in a housing 2 and rotates around a shaft 3 in the direction of the arrow. The injecting Electrode 1 is made of optically transparent glass 4, which is covered with a thin, optically transparent Layer 5 is coated from tin oxide or some other electrically conductive material. One for this electrode especially suitable material is under the name NESA glass from The injecting electrode 1, which is available from Pittsburgh Plate Glass Company, is designed as a cylindrical jacket part, which is arranged within the metal housing 2

The copying machine shown in "Figure 1 is _o in such a

jt

Position shown in which the injecting electrode is in a predetermined orbit on the way to a cleaning station A, at which several cleaning arrangements, such as ZoBo tapes 6, 7 and 8, contact the conductive surface 5 of the injecting electrode 1. On the other side of the injecting electrode there are stationary lamps 9, 10 and 11 within the machine frame 3, which are arranged opposite the strips 6, 7 and 8. When it is switched on, floodlight is sent through the translucent injecting electrode at its contact parts with the tapes. Each of the tapes is brought into contact with the injecting electrode 1 by one of the servomotors 12, 13 and 14. The servomotors press the tapes to clean the injecting electrodes Electrode against its electrically conductive surface ₀

The next treatment station in the orbit of the injecting Electrode is an illustration B. When the injecting electrode 1 is moved past the station for the first time B acts a first Bilcielektorodü 16 with the conductive

1098 ^ 2/1746

j.

Surface 5 of the injecting electrode 1 together _o

At a scanning station C, optics project a light image into the imaging zone of station B between the electrodes 1 and 16. Me Optik has a lamp carriage 17 which can be pivoted about a shaft 18 and moves back and forth in the direction of the arrow swings here. An original 20 lies on an object surface 19 · The lamps 33 are shown in their scan start position and move during the movement of the injecting electrode 1 through the imaging zone of station B over the object surface 19 and project over suitable Mirrors 21, 22 and 23 so / ie a lens optic 24 through the transparent electrode 1 through an image in the imaging station Bo

The picture electrode 16 designed as a roller rolls over the conductive surface 5 of the injecting electrode 1 and serves both to supply the image suspension to the injecting Electrode as well as for the imagewise distribution of the suspension between the injecting electrode surface 5 and the surface of the picture electrode 16.

The injecting electrode then rotates at a constant speed once through its entire orbit without with one of the treatment stations arranged along the orbit to work together until they return to the imaging etation B achieved by a servomotor 25 has meanwhile been the image electrode 16 from its the electrode 1 applied Position together with a housing 26 carrying the image electrode 16 also lowered another .Actuator 27 a carriage. 28 in the horizontal direction, which takes the housing 26 carrying the image electrode 16 with it. With the carriage 28 is a second image electrode 29 moved together with a housing 30 holding them

109822/1745 ^{BAD orig |} nal

Servomotor 31 lifts the housing 30 and at the same time the two image electrodes 29 in the imaging zone of the station B iT an eccentric disk 32. The second picture electrode moves over the rolling surface 5 of the injizieren- in electrode 1, as it moves through the Abbildungsstaion B. At the same time, the original 20 on the object plate 19 is illuminated again by the lamps of the scanning station C. The scanning movement is with the movement of the injecting. Electrode 1 synchronized so that a moving image is created congruent with the first projected image, which moves at the same speed as the electrode surface 5 in the imaging zone.

The injecting electrode 1 then arrives at a transfer station D which has a transfer roller 40 o A sheet 44 of transfer material held in a storage container 41 is conveyed from this via a suction conveyor 42 to the transfer roller 40. It is grasped by a gripping mechanism 43 located on the roller '40 and rotated towards the injecting electrode 1 which is just passing through the transfer station D. Before the sheet 44 touches the surface 5 of the injecting electrode 1, it is moistened with a liquid which promotes the transfer of the particles adhering to the surface 5. Moistening is effected by a moistening rod rotating in a supply of suitable fluid in the tank 46 . The transfer roller 40 rolls the sheet 44 over the surface 5 of the injecting electrode 1 under the influence of a suitable electric field from which the image on the injecting electrode-forming particles onto the sheet of transfer material transfers _o The sheet 44 is by stripper fingers 47 and a release mechanism the gripper mechanism removed from the roll 40

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The imaging takes place in the imaging zone B between the contacting injecting electrode 1 and a Image electrode instead · At this point of contact, the light-sensitive pigment parts are between the injecting Electrode and the picture electrode brought and an electric field and that of the optical imaging device C exposed to incoming light radiation

The image electrode assembly sits between two machine frame parts 100 and 101, see Fig. _O 2 and 3o The assembly slides on two rails 102 and 105 on nylon or other material produced with a low coefficient of friction rollers 104 and 105 ', the bearing at one arrangement carriage 28 are arranged to allow easy reciprocation on the rails 102 and 103. Further guide rollers 106 and 107 engage in rails of the base plate 108 of the copier and are also attached to the base of the carriage 28 in order to facilitate the movement of the base relative to the base plate and the injecting electrode 1 «)

The entire carriage 28 is moved back and forth by a servomotor 27, which is connected to the via a fork connection 109 Machine bottom plate 108 is connected. The end position of the servomotor 27 is set by an adjustable attachment 111 set with a flansoh 112 of a sole part 113 cooperated The side walls 114 and 115 of the carriage 28 limit the electrode arrangement and carry the guide rollers 104 and 105. Attached to the or integrated components of the carriage 28 are a first and a second picture electrode tank 26 and 30 »

Inside the first picture electrode tank 26, the picture electrode 16 is on either end of the tank in jacket heads

109822/1745

BATH ORIGINAL

117 and 118 held in side walls 119 and 120 shaft 116 attached. The first picture electrode tank is in two compartments divided up. The first is the suspension feeding department, the first picture electrode 16 and the associated mechanism for feeding and treating the suspension to this or where on this records. The tank consists of a side and middle wall 121 and 122 and a base plate 123 formed The second compartment of the first picture electrode tank 26 is the upper compartment, open on one side, containing various connections, motors, and similar puncture members the electrode arrangement picks up »

In the suspension feed section of the tank, a mechanism is provided with which a suspension layer is to be applied to the first picture electrode 16, which is necessary for the imaging process in the imaging zone.For this purpose, a suspension conveyor brush 125 is provided, with which the image substance suspension in the tank is fed to the picture electrode 16 This brush 125 brings the suspension from the bottom of the tank 26 to the surface of the first picture electrode 16. The brush 125 is attached to a shaft 126 mounted in bearings within the side walls 119 and 120 of the first picture electrode tank 26

In order for a smooth suspension base to reach the contact area between the first image electrode and the injecting electrode, a smoothing rod, such as a wire-wound rod 127, is provided which moves the image electrode 16 in contact with it other surfaces "have besehaffenheib, with a uniformly thin Suspenslonsschicht can be produced" the Glättungastange is KV / ei bearing arms 128 and 129 through to the 119 and 120 Üeitanwände üea at a aioh zv / iaohen the poor image

ι ü ya 11/1 ν 4 B

-H-

electrode tanks 26 extending shaft 130 held. These Shaft 130 is preferably a hollow shaft, one above which interacts with the surface of the first picture electrode 16 Smoothing bar applies evenly distributed force. The hollow shaft runs in suitable bearings through the tank wall 119 and is there pressed onto it with one Crank arm 131 connected

After contact with the suspension feed roller 125 and the smoothing rod 127, the first image electrode 16 in its orbit next cooperates with a shear roller 134, the task of which is to exert a shearing force on the image suspension layer before the imaging takes place, since it has been determined that some image material «Suspensions produce better color images after applying such a shear pressure. The shear roller 134 is brought into and out of engagement with the first picture electrode 16 by the mechanism described below, as required. The shear roller is mounted on a shaft 135 connected via a bearing to a crank arm 137 and via a second bearing to a similar crank arm on the opposite side. This mechanism can be seen in detail in Figo6. The hollow shaft 138 is also connected to the crank arm 137. A drive shaft 140 for the hollow shaft 138 runs through a bearing 139 provided in the crank arm 137. The hollow shaft 138 is, however, welded to the crank arm 137 so that the drive for pivoting the crank arm and thus the ijciherrolls; \ Ή touching the first picture electrode * - · the position shown · The IiohlwoLle 138 penetrates the tank wall 120 within a OiLi to storage ο

On four AuiJimu> from left to der Tunkvmnd 120 hit die WaILe 1 5β with iil.n ^ r TriiLbriew-.inucjheib'i I [7ί connected by a titöinn * - t LV! her L omen \\ J aa ^ u fcr bjbisa I.üU DU Treib t-itnajnsche ibe j- |. ·?

1098 * 2/1745 BADOR ₁ G ₁ NAL

is separated from the hollow shaft 138 via a bearing 144. This bearing 144 cooperates with a bearing 145 and allows rapid rotation of the gear 146, so that the Shear roller 134 over a chain 147 and a driven gear 148, which sits on the shaft 135 of the shear roll 134, can be driven at a higher speed. Rotation of shaft 140 relative to the combination of drive pulley 142 and gear 146 are prevented by a collar 149 provided on the outer end of the shaft 138.

The shear roller 134 is opposite the first picture electrode 16 electrically pre-tensioned in order to be able to exert even better shear effects «

Next, a knife edge bezel 150 is in orbit of the first picture electrode 16 arranged, the surface of which touched whenever it did not touch the injecting electrode. The knife-edge bezel 150 prevents the Image suspension from it, spread over the surface of the image electrode to be distributed if no image suspension is required will. The knife edge cover is on a crank arm attached, which is oriented in the rest state that the aperture does not touch the first picture electrode. The crank arm 151 has two planes 152 and 153, which are connected to a hollow shaft 155, which in turn is the knife edge cover 150 evenly against the surface of the first image electrode The hollow shaft 155 runs in suitable bearings through the side walls 119 and 120 of the first picture electrode tank 26 through onto a crank arm 156 fastened at one end, which rotated the hollow shaft 155 The knife edge With the help of this mechanism, the aperture 150 is in and out of contact with in the manner described below brought to the surface of the first picture electrode 16

The remaining compartment of the first picture electrode tank

109822/1745

26 takes the motor 157 for the Soherrolle 134 on, the

attached to the base plate 123 and via a gear 158 with

the timing belt 143 rotating the shear roller 134 isto

The last component that interacts with the surface of the first picture electrode 16 is a push-out diaphragm 159 »die is held in a storage block 160 and scrape off unused suspension and pigment particles from the first picture electrode 16 target. The bearing block 160 has an eccentric Shaft end 161 connected, which is held in an actuating arm 162 is · The adjusting arm 162 is attached to a suitable one by means of an adjusting screw 163 guided through a thread in the adjusting arm 162 Contact pressure is set and is supported against a stop 164 of the tank wall 119. A tension spring 165 holds the Actuating arm 162 in its correct position.

The surface 166 of the picture electrode 16 is made of a material

7 rial, which has an electrical resistance of 10 Ohmcm or greater than what is required to maintain proper electric field conditions in the imaging zone is »The surface 166 is therefore made of a barrier electrode material, such as from Tedlar, a polyvinyl fluoride film available from E.Io DuPont de Nemours & Co., or formed from baryta paper

The substrate 167 for the surface material 166 is an electrically conductive rubber-like material that, when touched is deformable with the injecting electrode 1 in the imaging zone ·

The second picture electrode 29 shows the same structure also has a high electrical resistance surface 168 and a deformable inner core 169. The two"

1 Λ ο ο ο ο / π / C BAD ORIGINAL

th picture electrode 19 therefore has the outer coating 168 the same barrier electrode material as the coating 166 of the first picture electrode 16. The second picture electrode is on top of one Shaft 170 is attached, the side wall 171 on a jacket head 172 and the side wall 173 on a jacket head 174 penetrates. Each of these clad heads holding the picture electrodes is provided with bearings so that the shafts and also the picture electrodes can rotate freely in the jacket heads. The second picture electrode 29 has the task of unwanted Background particles from the on the injecting electrode 1 image formed and to improve this image as a whole »However, it does not bring any further image material suspension onto the injecting electrode 1, as does the first picture electrode »

So that the second picture electrode can optimally fulfill its task, the use of one of the carrier liquids has been found the suspension similar or even the same liquid for coating the surface of the second image electrode as proved very beneficial. For this purpose, brushes 175 and 176 apply liquid to the outer surface of the second picture electrode 29, which liquid is at the bottom of the second picture electrode tank 50 is located. A scraper plate 177 is supported by a bearing block 178 pressed against surface 168 to release the liquid to be removed from it again, this prevents contaminated liquid from reaching the imaging zone. Each of the cleaning brushes 175 and 176 has a shaft 179 and 180 which support the side walls of the second picture electrode tank 30 penetrate. On the bottom plate 181 of the tank 30 is a bracket 182 for a motor 183, which the Cleaning brushes 175 and 176 rotates.

A tank wall 184 has a liquid outlet near it Top edge. The for coating the surface 168 of the wide Image electrode 29 required liquid is through a

1 0 9 ß 2 2/1 7 4 B

The slot 185 extending across the entire width of the wall 184 is output. This allows fresh liquid for the second image electrode must be continuously fed. » The liquid arrives at the inlet 187 shown in FIG Slot 185o

During operation of the electrode arrangement, the slide 28 is moved back and forth below the injecting electrode 1 » Either the first picture electrode 16 or the second picture electrode 29 are thereby grounded in the imaging zone B in brought a position contacting the injecting electrode 1 at which a light image of the original to be copied is projected. This is done by lifting either the first or the second picture electrode tank with all associated Components causes. As can be seen from the drawing, the tanks are in a first position by the servomotor 17 at which the first picture electrode contacts the injecting picture electrode. The first picture electrode tank 26 is then raised from its lower rest position, which is caused by the servomotor 25, which is via a fork connection is connected to a crank arm 190 fixedly connected to a shaft 191 which carries an eccentric disk 192

The first picture electrode tank 26, which is moved by the servomotor 25 in cooperation with the eccentric disk 192, is also mounted on a second eccentric disk connected to a second shaft 193 for reasons of balance, which is also below the first image electrode tank is located. When actuating the servomotor 25 rotates servant the shaft 191 over the crank arm 190. In addition to lifting the tank by the Ex, he pulls disk 192 over a On the shaft 191 seated gear wheel I95 driven chain 194 the corrugation showing the other torso-excentric disk «193. Serve doubly provided shaft and eccentric disk arrangement

BATH ORIGINAL 109822/17 4 5

tion is particularly advantageous because the tank has heavy components, namely the first picture electrode 16 and its associated Components, at one end, and also heavy components, like the shear roller motor 157 'on the other · It is important to keep the tank balanced and balanced to prevent sloshing of liquids to prevent in the tank and the correct position and location of the first picture electrode 16 opposite the injecting To be able to adhere to the electrode.

The various cooperating with each of the picture electrodes Components can be made by pneumatic or hydraulic servomotors as well as electrical and / or mechanical devices moved and operated so that they function in the manner described in the embodiment shown here o

When the copier starts operating, the first image electrode is 16 arranged below the imaging zone B ready for contact with the injecting electrode 1. Moves the injecting electrode 1 into the contact area of the imaging zone B, the servomotor 25 is actuated, which the crank arm 190 takes along and rotates the eccentric disc shafts in such a position in which the first picture electrode tank 26 sits on the highest point of the eccentric discs. The entire tank moves up a certain distance and brings the first picture electrode 16 into the injecting one Position of the electrode in contact with the surface. The image suspension is continuously fed to the surface 166 of the first image »electrode 16 and the smoothing bar leaves only one dosed amount of suspension to the shear roller 134. The G-lät « processing rod 127 is thereby made by rotating the hollow shaft 130 via the crank arm 131 with the surface 166 of the first Image electrode 16 brought into contact and with a predetermined Contact pressure through the leather 251 in this position

1 0 9 8 2 2 I 1 7 L 5

held

The shear roller mechanism is actuated to move the shear roller 134 with the suspension on the surface 166 of the first To bring picture electrode 16 into contact. The hollow shaft the shear roller 134 is held on the crank arm 252, which is connected to a servomotor 254 via a fork connection is. When the servomotor 254 is actuated, it brings the shear roller 134 to the first via the aforementioned lever mechanism Picture electrode 16 in contact.

The measurer edge diaphragm 150 is made from the surface 166 brought the picture electrode 16 touching position and the supplied and metered and exposed to a shear pressure Image suspension arrives in the imaging zone B in order to be there to be selectively deposited on the injecting electrode 1 in an imagewise distribution. The suspension that doesn't contributes to the image forming on the injecting electrode, which is moved by it, is determined by the Image electrode 16 taken along and held in storage 160 with Expressing diaphragm 159 brought into contact. From this, the suspension is removed from the surface 166 before new suspension is fed to the picture electrode with the feed roller 125

After the injecting electrode 1 has been moved through the imaging zone B, the servomotor 25 is switched off and the first picture electrode tank 26 is lowered again. The servomotor 27 for the carriage 28 is switched on and the carriage with both picture electrode tanks 26 and 30 in the representation shown in Figures 1 and 3 naoh The servomotor stops this movement when the second picture electrode tank 30 reaches such a position has that the second image electrode 29 is located immediately below the imaging zone »

109822/1745 ßAD original

- el -

When the injecting electrode 1 moves through the again Imaging zone B, the second picture electrode tank 30 is set by actuating the servomotor 31 and rotating the eccentric disk 211 naoh above "until it has reached its highest position on the eccentric disk. Before the second picture electrode 29 moved into the imaging zone it is sprayed with a liquid that is similar or equal to the carrier liquid of the image material suspension « This makes it easier to loosen the particles to be removed from the image on the injecting electrode 1. Since the movement of the two electrodes 1 and 29 under the same imaging conditions as when contacting the When the first picture electrode 16 is played, the picture on the injecting electrode surface 3 is removed by removal the particles struck with activating light radiation amplified by the from the optical imaging device 0 projected light is given.

As the second picture electrode 29 rotates through its orbit the surface 168 becomes more of any remaining Suspension cleaned by cleaning brushes 175 and 176. The surface becomes through the push-out aperture 177, which in a bearing 178, wiped clean and relatively dry. The contaminated liquid coming from the surface 168 of the second picture electrode has been removed, is also the second picture electrode tank 30 by means not shown here removed to be filtered or otherwise refurbished via the spray device in the wall 184 to the to be returned to the second picture electrode tank,

Then the injecting electrode 1 sioh through the fig- ' the second picture electrode tank becomes 30 lowered into its rest position by switching off the servomotor 31. The servomotor 27 is again a - stopped so that the sled with the tanks was back again

109822/1745

is moved into its starting position, from which an imaging process can be started again.

Located; the first picture electrode 16 is not in its imaging position, so when the servomotor 25 is switched off, the knife edge screen 150 with the surface 166 of the first Image electrode! 6 brought into contact. This is achieved by switching on a servomotor 255 that controls the crank arm 156 moved to the right in FIG.

The actuators shown here may operate hydraulically or pneumatically, or may by electrical, for example, electromagnets or mechanical components, Z ₀ B. Focke discs are replaced ₀ However, it v / earth, combinations of the aforementioned components used fulfill the functions mentioned »

The required electrical voltage is provided by an electrical Connection 215 and contact brushes 216, which touch the shaft 116 of the first picture electrode, »The voltage source itself is not shown, but should be strong enough to handle voltages from 300 volts to 5000 volts to be able to generate on the surface of the picture electrode touching the injecting electrode 1.

The components arranged around the second picture electrode 29 are not brought into and out of engagement with the second picture electrode, nor are they dependent on the current status of an imaging cycle, as are some of the components assigned to the first picture electrode. Both cleaning brushes 175 and 176 remain in constant contact with the surface 168 of the second picture electrode 29. For "pressure aperture 177 exerts a constant pressure on the surface \ b3 of the second picture electrode, through the setting

109822/1745 ORIGINAL BATHROOM

the aperture bracket 178 is adjustable. The one you want Pressure is achieved by rotating a crank arm 220 and adjusting a set screw 221, this Position is maintained by a tension spring 222. The crank arm 220 is with the eccentric shaft 223 of the visor bracket 178 connected. The shaft 179 of the cleaning brush 175 and the shaft 180 of the cleaning brush 176 are via bearings in both side walls of the second picture electrode tank 30 stored. To the shaft 170 of the second picture electrode 29, an electrical voltage is applied via an electrical connection 225 and contact brushes 226.

The cleaning brushes are connected to a gear 230, a chain 231 and another gear 232 that connects to the shaft

179 the cleaning brush 175 is connected by a motor 183 powered. A chain 233 is connected to a gearwheel arranged coaxially to the gearwheel 232, which is connected to the shaft

180 of the other cleaning brush 176 driving gear 234 rotates. A tension roller 235 holds the chain 233 on the Gears,

Both picture electrodes are connected to a common chain 240 going out from the main drive of the copier machine. drove. This chain 240 drives a gear wheel 241 on the first picture electrode and a gear wheel 242 on the second picture electrode, so that the two picture electrodes are synchronous rotate with the injecting electrode 1 when they are together come into contact. A tension pulley 243 mounted on an arm 244 prevents the chain 240 from being dislodged from the sprockets 241 and 242 can jump off. Because the gears and the picture electrodes driven by them are positioned relative to one another move, this tension roller 243 is particularly well suited to the chain 240 over a sufficient number of teeth of the gears to prevent the chain from jumping off.

109822/1745

Claims (1)

Claims Electrode arrangement with image material supply, in particular for a copying machine operating according to the photoelectrophoretic imaging process, characterized by a picture electrode (16) movably mounted in a tank (26), which can be moved past a certain point is, and by one of the surface (166) of the picture electrode (16) during its movement and before reaching the specific Place image feeder (125, 127). 2. Electrode arrangement according to claim 1, characterized in that the picture electrode (16) at least partially is electrically conductive and that a switching device (215, 216) for connecting the picture electrode (16) with a electrical voltage source is provided ο 3 electrode arrangement according to claim 1 or 2, characterized in that that a surface (166) of the picture electrode (16) on the feed device (125, 127) and the first drive (240, 241) moving past the specific point is provided «, 4. Electrode arrangement according to one of claims 1 to 3 »characterized in that the picture electrode (16) has a Cleaning device (159 »160) is assigned with the during their movement and after passing the specific point image material remaining on its surface (166) can be removed «. 5ö electrode arrangement according to claim 4, characterized in that that the cleaning device (159, 160) has a contact surface (166) of the picture electrode (16) 109822/1745 has pushing cover (159) o 6. Electrode arrangement according to claim 5 »characterized in that that the ejector diaphragm (159) is held in a bearing block (160) which is connected to the ejector diaphragm (159) is connected to the second drive (161, 162, 165) moving relative to the surface (166) of the picture electrode (16) * 7. electrode arrangement according to one of claims 1 to 6, characterized in that the image electrode (16) is cylindrical is trained. Electrode arrangement according to one of Claims 1 to 7 »characterized in that one with the picture electrode (16) cooperating and on its surface (166) a Shear force exerted during the movement of the image electrode (16) and before reaching the specific point Shearing device (134) is provided. 9 «Electrode arrangement according to claim 8, characterized in that that a shear device (134) with the picture electrode (16) in and out of engagement moving third drive (254) is provided. 10. Electrode arrangement according to claim 8, characterized in that a fourth drive (157) for rotating the shearing device (134) is provided. 11o electrode arrangement according to one of claims 1 to 10, characterized in that the feeding device (125, 127) a feed member (125) coating the picture electrode (16) with picture material and one between sioh and image material moved through the picture electrode surface (166) has dosing smoothing device (127), in the direction of movement of the image electrode (16) behind 109822/1745 the feed member (125) is arranged. 12. Electrode arrangement according to claim 11, characterized in that that the smoothing device (127) is a smoothing rod " 13. Electrode arrangement according to claim 11 or 12, characterized in that the smoothing rod (127) with the picture electrode (16) in and out of engagement moving fifth drive (130, 131, 251) is provided. 14. Electrode arrangement according to claim 13, characterized in that that with the fifth drive (130, 131 »251) an approximately even pressure from the smoothing rod (127) can be exercised on the picture electrode (16). 15. Electrode arrangement according to claim 14, characterized in that that the size of the pressure can be adjusted via a setting device (130, 131) » 16. Electrode arrangement according to one of claims 1 to 15, characterized in that the picture electrode (16) is assigned a knife edge screen (150) which the Touched the image electrode (16) at a point in front of the specific point of the orbit 17. Electrode arrangement according to claim 16, characterized in that that a Mesaerkanfcenblende (150) with the Image electrode (16) moving sixth drive (255) into and out of engagement is provided. 18. Electrode arrangement according to one of claims 1 to 17, characterized in that the tank (26) has a feed department (121, 122, 123) with a storage space BATH ORIGINAL 10 9 822/1745 for the image material contacting the feed member (125) and a housing part (119, 120) holding the picture electrode (16) and a bearing part serving for fastening (123). 19p electrode arrangement according to one of claims 1 to 18, characterized in that the specific point of the orbit of the picture electrode (16) is the imaging zone (B) of a copying machine, on which the picture electrode (16) touches a surface representing an injecting electrode (1) , on which an image can be generated from the image material suspension, _etc. 109622/1748 ZS. Blank page