DE2162086A1 - Process for developing electrostatic latent images - Google Patents

Description

Patent attorneys Dipl.-Ing. F. Weickmann,

Dipl.-Ing. H. Weickmann, Dipl ^ Phys. Dr. K. Fincke Dipl.-Ing. F. A. Weickmann, Dipl.-Chem. B. Huber

XPR

8 MUNICH 86, DEN 3CEROXGORPORATIOn, POSTBOX 860 820

Xerox Square, Mohlstrasse 22, phone number «3921/22

Rochester, N. Y. 14-603A.St.A, <98392i / 22>

Process for developing electrostatic latent images

The invention relates to a method for developing electrostatic latent images by means of a donor element loaded with developer material.

In electrophotographic reproduction technology, a Electrostatically charged photoconductive surface and then irradiated with a light pattern of the information to be reproduced, creating an electrostatic latent image the photoconductive surface is created. Toner particles that consist of a finely divided, pigmented synthetic resin material can be brought up to the latent image and bonded to the photoconductive surface. The resulting Toner image can be fixed on the photoconductive surface or transferred to another image carrier and fixed on this will.

A well-known method of developing latent electrostatic Images is the so-called transfer development. This generally consists in adding a layer of toner a photoconductive recording medium provided with a latent image is brought up, the toner particles transferred from the layer to the parts of the image

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be genes. One embodiment of this method uses a donor element to which the toner particles are applied, after which the donor element is brought close to the surface of the photoconductor. In the small distance, the toner particles of the toner layer of the donor element are attracted by the recording medium, since this electrostatic charges contains. In this way the latent image is developed. In this process, the toner particles have to overcome an air gap in order to

fc parts to achieve on the photoconductive layer. In two other transfer methods, the dispenser loaded with toner is brought into contact with the recording medium so that there is no air gap . According to one embodiment of this method, the dispenser loaded with toner is brought into rolling contact with and removed from the recording medium in a non-sliding manner, so that the electrostatic latent image is developed at a rapid step. In another embodiment of this method, the carrier loaded with toner is moved in a sliding movement over the recording medium. A sliding movement in the order of magnitude of the width of the thinnest line is used to develop a

"available line perpendicular to the sliding motion The amount of toner doubled, and the sliding effect can be intensified to achieve a higher density or area coverage.

A "transfer development ^11" can therefore be understood as a development process in which 1. the toner rail does not touch the photoconductive recording medium and the toner particles have to overcome an air gap for development, 2. the toner layer is brought into rolling contact with the recording medium and 3. the toner layer with it brought into contact with the recording medium and guided in sliding motion over the image surface.

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ORIGINAL INSPECTED

development is also called "touchdown development" known.

In a typical transfer development process, a cylindrical or endless donor element is rotated so that its surface can be brought up close to the moving surface of a photoconductive drum which is provided with an electrostatic latent image. Several process stations are provided on the circumference of the donor element, for example a loading station at which the toner is brought onto the donor element, a station for removing toner agglomerates from the donor element, a charging station for uniform electrostatic charging of the toner particles on the donor surface, a cleaning station at the the toner layer is given a uniform thickness and agglomerates that have not yet been removed are removed, a development station at which the toner particles are transferred to the photoconductive recording medium provided with the latent image, and a cleaning station at which a neutralizing charge is applied to the remaining toner particles is applied and at which a cleaning element removes remaining toner from the peripheral surface of the donor element. In this way, one more ode "^'one gives less kontinuier! I rather Entvicklungsvorgann :.

■ ^ a usable dispenser element is partially covered by US Pat. No. 3 20? 394- known. It has an electrically conductive ink in the form of a cylinder, a thin electrically conductive layer on this base and a continuous, electrically conductive grid pattern on the insulating layer. The grid pattern is connected to an electrical ring core t ;;> l: t, sr dn ^! ? its potential during different stages of the doR process. · =

? 0 9 8 ;: r-! 0 9 /, 9 _BAD 0FttG » ^NAU

changed between earth potential and a charge potential can be. With such a donor element, a large number of strong marginal fields or micro-fields are created on the surface generated. When it comes into contact with the toner particles, the toner particles acquire triboelectric charges so that the toner is charged with the same polarity as that of the screen. In this way, the Toner repelled into the gaps in the grid. The donor element is then loaded with toner.

A disadvantage of this method with a dispenser of the type described Kind is that different potentials or voltages are required at the different treatment stations and that the donor element cannot operate at different potentials at the same time. For example, if a potential of +500 volts is required in the area of the loading station while the dispenser element is in the area the charging station must carry earth potential, these two treatment processes cannot be carried out at the same time will. While the donor element carries the potential of +300 volts, it must be continued with this potential, making at least one complete revolution in order to charge the entire circumferential surface. Here must but the potential of the grid can be changed to ground potential, so that the charging process at the charging station only during another complete revolution can take place. The charger brings a uniform electrostatic Charge on the layer of toner particles present on the donor element. Then the potential of the Raster can be brought back to a value that is suitable for the treatment step at the cleaning station is. Here the potential of the cleaning roller is set so that it is approximately the background potential of the the recording medium provided with the latent image

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speaks. If the background potential of the recording medium is, for example, +200 volts, then the potential the cleaning roller is approx. +100 volts, while the potential at the dispenser element is approx. +300 volts .. The voltage or potential on the donor element is set to this value and the donor element is at least moved one full revolution so that the cleaning roller can remove the toner, which otherwise would be present in the background areas of the recording medium subsequently provided with an image. Thereafter the potential of the raster during its movement in the direction of the recording medium must be adjusted so that it is suitable for transference development. Guide the image area parts of the recording medium, for example a potential of +700 volts, the flas potential on the grid of the donor element can be approx. +300 volts. After The surface of the donor element must be treated to "remove the ghost image or a residual image of its" development Remove surface. This is done by applying a neutralizing charge to the toner particles a loading device. To this end, a change in the potential of the grid to ground potential is again required. That The dispenser element can then be moved by at least one further revolution while all other functions are interrupted are.

The main disadvantage of the development process described above is therefore that the various treatments for the donor element take place one after the other and cannot be carried out at the same time.

The object of the invention is to provide development processes to improve the type described above and to shorten their time sequence. For this purpose, the

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Donor elements work in such a way that several functions of the Transfer development are feasible at the same time.

A method of the type mentioned at the outset is designed according to the invention to achieve this object in such a way that a donor element in the form of an endless, electrically conductive base with a continuous dielectric layer, which with several electrically conductive grids, of which at least two are insulated from each other, with one Reference potential connected to the base at several treatment stations including a loading point for toner particles and a development point for the latent image to be developed is passed that a the program control independently setting the electrical status of each grid in relation to the base according to the potential suitable for the respective processing station is provided and is continuously held in contact with each grid and a reference voltage source and controls a charge source in accordance with its program and that the treatment functions at the treatment stations carried out at points in time which overlap one another during the transport of the donor element will.

A dispenser element for carrying out the method has an endless, electrically conductive base with a continuous one dielectric layer on which a plurality of electrically conductive grids are arranged, of which at least two are electrically isolated from one another, and also a reference potential source connected to the conductive base and means for changing the electrical potential of each raster independently.

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The method according to the invention or the dispenser element operating according to this method enables a very advantageous one Construction of an electrostatic latent image developing device. Inside such a device there are also other treatment stations on the perimeter of the Donor element may be provided. A charging station can be between the loading station for the toner and the development station can be provided. It contains a loading device, with which a uniform electrostatic charge is applied to the toner particles of the donor element with one polarity opposite to that of the latent image when a positive development is applied instead of a Reversal development is required. A station for removing toner agglomerates can be located between the charging station and the toner supply station and the toner agglomerates and loosely on the toner particle layer Remove adhering particles by vacuum. A cleaning station can wipe the charging station and the development station be provided, it then expediently works with a rotatable Eylindrical cleaning element, which is located near the donor element and contacts the outermost portion of the toner particle layer. The cleaning element is designed so that the layer of toner particles held on the donor element is comparatively uniform Bead receives so that any remaining toner agglomerates are removed. Between the development station and a loading device of the cleaning device may be associated with the toner supply station, both of which Arrangements after development take effect. They each serve to neutralize the charge on the toner particles and to facilitate the removal of these particles by the cleaning device.

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In carrying out the development process of the present invention the donor element is thus guided past several treatment stations. These stations include the toner loading station, at which a toner particle supply is provided, furthermore the development station at which the toner particles through the donor element into a development relationship with the respective electrostatic latent image to be brought. The pad of the donor element is on Earth potential held. The ones to independently change the electrical state of each grid of the donor element opposite its support provided devices that the potential between ground potential and a charging potential change are programmed according to the potential, which is a suitable one for each treatment station Operating condition supplies. Electrical contact is maintained between this device and each grid. A source of earth potential and a source of charge potential are assigned to this programmed device and are activated according to the program. The function at the respective treatment station can then be carried out simultaneously with the other functions during transport the surface of the donor element past these stations.

Additional procedural steps can be found in the basic procedure be provided. For example, the toner agglomerates can be removed before uniform charging, cleaning takes place after uniform charging and a residual image can be removed after image development.

The invention is described below using an exemplary embodiment shown in the figures. Show it:

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Fig. 1 is a sectional view of a working according to the invention electrophotographic reproduction machine and

2 shows a perspective illustration of part of a dispenser element designed according to the invention.

The development method according to the invention is a transfer development, in which the toner particles in a special way to an electrostatic latent image on a photoconductive recording surface can be applied to develop this image. Such a development process is described below for its application in an electrophotographic reproduction machine, in which a latent electrostatic image through uniform electrostatic charging and image-wise irradiation is generated, but it can also be used in the same way in other reproduction machines in which a latent image is to be developed by applying toner. Under a recording medium that is suitable for such a development is to be understood as any medium on which an electrostatic latent image is produced can be.

1 shows a reproduction machine which contains a recording medium in the form of a drum 10, the surface of which is guided past stations A to E in the direction of the arrow shown. The drum has a light-sensitive surface, for example made of a selenium layer provided on a conductive base. A latent electrostatic image can be created on this surface. The various stations on the circumference of the drum for carrying out the individual process steps are a loading station A, an exposure station B _9, a development station G, an image transfer station D and

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a cleaning station E. The stations A ₁ B, D and E are formed in more or less conventional technology and fulfill their i) ® ^we il ^s intended function. Station C is assigned to a device operating according to the invention; the other stations do not belong directly to the invention.

A charging device 12, for example a corotron, is provided at station A, which provides a uniform electrical

^ static charge applies to the photoconductive layer. While the drum is rotated, projected an exposure device 14, such as a projector, a light pattern on the charged surface of the drum 10, The electrostatic latent image thus generated on this surface is finely divided by applying a pigmented synthetic resin powder, the so-called toner, on the Developing station G developed or made visible. After the image has been developed at station 0, it is guided past the image transfer station D, at which an copy sheet 16, a loading device 18 and a fixing device 20 are provided. After the image transfer and the fixing of the developed image on the copy sheet, the

"The drum surface moves past the cleaning station E, on which a cleaning device 22, for example a rotating brush, is provided. At the development station 0 a dispenser element 24 is provided, which is more detailed is described. It is located near a toner container 26 which contains a supply quantity of toner 28. This dispenser roll 24 is provided so that part of their Circumference comes into contact with the toner 28. She is further arranged so that a narrow air gap between the surface of the drum 10 and the outer surface of the toner layer on this role 24 arises. This gap can

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have a width of approx. 0.025 to 0.25 mm.

Because of difficult to control conditions, some of the toner particles can agglomerate and become deposited on the surface of the donor roll protrude beyond the middle thickness of the toner layer. Furthermore, thicker areas of the toner layer can be used in the absence of a device for adjusting the thickness of the toner layer between the surface of the donor roll and the surface of the photoconductive layer within the development zone are compressed and likewise Generate agglomerates.

In order to ensure removal of the agglomerates and also the thickness of the toner layer in the area of the photoconductive To set the drum is a vacuum device 30 located near the periphery of the donor element at a location between the toner container and the development zone. the The vacuum device can advantageously be designed as a narrow slot, the length of which is somewhat greater than the width the toner layer is. This slot forms part of a vacuum line. This has a small distance to the surface the toner layer and creates a sufficient force through the negative pressure, the toner agglomerates and loosely Adhering toner removed from the toner layer. This force can be carefully adjusted so that only a uniform layer of toner particles necessary for development on the surface of the donor element remains behind.

Between the vacuum device 30 and the development zone is a charger 32, such as a corona discharge device arranged, which applies a uniform electrostatic charge to the toner particles,

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the polarity being opposite to the polarity of the latent image on the photoconductive drum.

Sometimes it turns out that the vacuum device 30 does not completely remove all agglomerates, and therefore not does not produce a desired uniformity of the toner layer. This can depend on the type of toner used or be caused by the respective type of loading of the dispenser element. If such a state occurs, the Removal of the toner agglomerates and the evenness of the toner layer by a cleaning or conditioning element 34 can be achieved, which between the charging device 32 and the development zone. This role 34-can apply an electrical bias and remove agglomerates and loosely adhering toner by electrostatic attraction. The role 3 ^ can be provided with a smooth surface and rotated at a speed matching that of the donor roll. A bias from +100 to +200 volts is satisfactory in removing residual agglomerates and loosely adhering toner Results. Otherwise, these amounts of toner were removed from the background areas of the image on the recording medium dressed and bound. If a pre-tensioned conditioning roller of this type is used, you must The distance to the surface of the donor element should be adjusted so that only agglomerates and loosely adhering particles removed from the toner layer. This distance is advantageously set to 0.025 to 0.25 mm. Further it is favorable, together with the processing element 34-one To use a cleaning mechanism that removes the toner particles and agglomerates that are attached to the toner layer peeled off or electrostatically peeled off and adhering to the surface of the conditioning roll. This cleaning mechanism can be a brush 36, which together with a

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Vacuum system 38 operates, which removes the toner particles pulls off the cleaning brush.

After the evenly charged toner layer of agglomerates is free and has a practically uniform thickness, it becomes the image to be developed on the recording medium and the transference development described above occurs. Since the toner layer has a uniform If the thickness is thick, the toner is not expected to stick together. This property together with the lack of it results any agglomerates a copy of excellent image quality.

After development, the dispenser roll is used for renewed loading prepared with toner, including the remaining toner of a neutralizing charger 4-0, for example a! corotron. This will shape the removal of residual toner with a cleaning device a rotating brush 4-2, which is a vacuum device 4-4- is assigned. The dispenser roll is thus removed from a ghost image or residual image of the previous one Image freed and prepared to accept a new supply of toner.

In Pig. 2 shows part of a dispensing element according to the invention. The element 4-6 is part of a metal drum, for example an aluminum drum, on the surface of which a dielectric layer 4-8 is provided. This can be a dielectric lacquer, for example. Over the dielectric layer 4-8 is a conductive one Grid pattern 50 arranged. The one for this grid pattern Material used can be any suitable conductive material be, for example silver, coppertew. The exposed ones dielectric areas 52 are thus surrounded by conductive material of the grid. The electrically conductive base

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layer 46 is electrically grounded in a suitable manner, including an indicated earth line 58 is used. The base can also be connected to a suitable reference potential in some other way be.

The donor element can be made in any suitable manner The procedure described below is only an example. An aluminum drum is used here coated with a thin layer of dielectric lacquer. A thin layer of copper is placed over the entire surface of the dielectric lacquer applied. A thin layer of a suitable anti-etch material is applied applied to the copper surface. A grid pattern is applied to the surface using known photographic processes of the anti-etch material. This pattern may contain several grid patterns of the type shown in FIG. It Thus, two or more grid patterns can be created on the surface of the donor element. Every grid pattern is electrically isolated from the adjacent pattern on the surface of the donor element. Then the radiated Pattern developed and etched into the copper film · The remaining anti-etching material is applied to suitable Way removed, for example by a solvent. A thin dielectric layer of about 0.006 to 0.012 mm Thickness can be applied to the grid pattern for protective purposes. An earth connection with the aluminum drum can be prepared in a manner known to those skilled in the art. For example, a contact brush on the inner surface the aluminum drum can be provided, which is connected to earth via an electrical line. Then be electric Connections from the grid pattern 50 to a controller manufactured, which can switch each grid musjer to earth potential or some other predetermined charging potential.

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The electrical contact 60 and the segmented slip ring 62 are only shown schematically in FIG. 2. In the In practice, the contacts 60 are arranged on the inside of the donor element so that they are opposed to sliding contacts of the conductive bracket, but are electrically connected to each grid pattern. In a similar way The other ends of the contacts 60 can be in sliding contact with the segments 64 of the slip ring 62. A voltage source 66 can provide the appropriate potential for each segment of the slip ring. In this way the electrical contact 60 of each grid pattern may be in electrical communication with a segment of the slip ring 62, which works as a program control device. Depending on the position of each grid relative to the various stations on the circumference of the donor element can either be ground potential or a predetermined one Can be switched on automatically.

In the case of a development system with six process stations on the circumference of the dispenser element, i.e. 1. a toner loading station, 2. an agglomerate removal station, 3. a loading station, 4 ″ a processing station, 5 · a development station and 6. a cleaning station, the dispenser element 6 can have electrically isolated grid patterns, and the electrically segmented slip ring can be programmed to do that for the stations results in a suitable potential, such values are, for example, for the order of the stations indicated above at +300 volts, +300 volts, ground potential, +200 volts, +350 volts and ground potential.

With this arrangement, each individual grid pattern can be set to one of the various processing stations with the potential suitable for the respective station

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tial is reached automatically and at the same time the other potentials be set differently accordingly. The slip ring can be programmed in such a way that it has the respective potential values for example from individual potential sources and grounded elements to the grid patterns.

The dispenser element has been described above as a cylindrical element, but it can also be an endless belt be designed, which moves the toner from the toner source to the various process stations.

Due to the special execution of the method according to the invention and the donor element used, it is no longer necessary to perform the various punctures to carry out the various processing stations one after the other, but these can more or less simultaneously take place. This enables better control of the

entire developing system is possible, and the time required for developing each image becomes significantly shortened.

Usual drive elements, so motors, belts, etc., are used to move the various movable elements in a known manner.

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Claims (12)

Claims ί 1.) A method for developing electrostatic latent images by means of a donor element loaded with developer, characterized in that a donor element 'in the form of an endless, electrically conductive base with a continuous dielectric layer, which has several electrically conductive grids, of which at least two against each other are isolated, with a reference potential connected to the base at several treatment stations including a loading point for toner particles and a development point for the latent image to be developed so that the electrical state of each grid relative to the base corresponding to that for the respective processing station suitable potential independently adjusting program control is provided and constantly in contact with everyone? Rasterization is held and controls a reference voltage source and a charge source in accordance with their program and that the treatment functions are carried out at the treatment stations at times which overlap one another during the transport of the donor element. 2. The method according to claim 1, characterized in that between the feed point for toner particles and the development point for the latent image to be developed at a point in front of the development point uniform electrostatic charging of the toner particles on the donor element with opposite polarity that of the latent image is performed. 209828/0949 3. The method according to claim 2, characterized in that between the charging and the charging with toner particles a removal of toner agglomerates by means of a vacuum device is carried out, which further removes loosely adhering toner particles from the toner particle layer . 4. The method according to claim 2 or 3, characterized in that a processing between the charging and the development the toner particle layer is carried out, wherein P by means of an electrically preloaded, rotatable, cylindrical Processing element near the donor element, the outermost region of the toner particle layer is touched and the processing element with removal of any toner agglomerates creates a uniform layer thickness. 5. The method according to any one of claims 2 to 4-, characterized characterized in that between development and charging of toner particles there is a charge and a decrease is carried out, wherein the charging is carried out with the toner particles neutralizing charges which the Reduce the removal force required for cleaning. 6. donor element for performing the method according to any one of claims 1 to 5 »characterized by an endless, electrically conductive pad (4-6) with a continuous dielectric layer (4-8) on which a plurality of electrically conductive grids (50) are arranged, of at least two of which are electrically insulated from one another by one connected to the conductive base (4-6) Reference potential source (58) and through a device (62) to change the electrical potential of each grid independently. 209828/0949 7. Development device for performing the method according to one of claims 1 to 5 »characterized by a between the loading point for toner particles (28) and the development station (C) before the development station (C) arranged charging device (32) which a uniform charge on the toner particle layer present on the donor element (24) brings up. 8. Apparatus according to claim 7 »characterized in that that between the loading device (32) and the loading point for toner particles, a device (30) for removal of toner agglomerates is provided, the next to the toner agglomerates loosely adhering toner particles from the Toner particle layer removed. 9. Apparatus according to claim 7 or 8, characterized in that between the loading device (32) and the Development station (C) a processing device (34) in the form of a rotatable, cylindrical processing element near the dispenser element (24) arranged in this way is that it contacts the outermost portion of the toner particle layer and gives it a uniform thickness as well Toner agglomerates removed. 10. The device according to claim 9 »characterized in that that the processing element (34) is an electrically prestressed cylindrical element with a smooth surface. 11. The device according to claim 9 or 10, characterized in that the processing element (34) has an adhesive Toner particles removing cleaning device (36) is assigned. 209828/0949 12. Device according to one of claims 7 to 11, characterized characterized in that between the development station (C) and the loading point for toner particles' (28) a loading device (4-0) and a second cleaning device (4-2) are arranged, the loading device (4-0) after the development process the charges of the toner particles for their better removal by the second cleaning device (4-2) neutralized. 7 0 9 8: ■ 'w π fU 9