DE2255745A1 - METHOD AND DEVICE FOR IMAGE DEVELOPMENT IN ELECTROSTATIC MULTIPLING DEVICES - Google Patents

Description

Xerox Corporation, Rochester, N.Y. / UNITED STATES

Process and apparatus for image development in electrostatic duplicating machines

The invention relates to a method and a device for electrostatic image development in both electrographic and electrophotographic duplicating, Copy, write or print. The same applies to the electrophotographic process as to the electrographic process Process an electrostatic charge pattern

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or a latent image recorded on an image pickup part, which, in the case of the duplication, which is primarily to be considered here, corresponds to the original to be reproduced. In which electrophotographic process according to the US patent 2,297,691 a photosensitive element with a photoconductive and insulating layer is charged almost uniformly. The charged and photoconductive surface is then exposed to the image of the original to be reproduced. at This process dissipates the charge at the exposed areas, so that a latent, electrostatic image is obtained on the photoconductive surface. With the electrographic Duplicating or printing becomes a latent electrostatic image according to the original to be reproduced without use made of photosensitive material.

Regardless of the method used to form the electrostatic latent image, visual record is usually obtained by depositing toner particles thereon, ie, developing the image. Development can be carried out by bringing the latent image into contact with a mixture of developers. Typical of the developer mixtures used here are toner particles, for example colored, thermoplastic particles, which adhere electrostatically to a coarser carrier granulate, for example ferromagnetic granules.

The cascade development, magnetic brush development, powder cloud development and liquid development are also known. The invention works with a hybrid system that combines cascade and powder cloud development. Such a hybrid development system is the subject of US Pat. No. 3,470,009. The developer system disclosed therein contains a bucket conveyor for transporting a developer mixture from a sump or storage container to a higher area. The developer mixture trickles in a cascade from this higher area

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down between a perforated screen or grid and an electrode. The toner particles are from Separate carrier granules move through the. Umbrella through, while the carrier granulate is retained on this. Some of the toner particles enter the space around the latent image in the form of a cloud. That produced by the latent image electrostatic field · attracts the toner particles and makes this makes the image visible.

Such a hybrid development system is excellent for reproduction with continuous tint and extension over fixed areas. On the other hand, see the well-known Devices do not provide any measures to recycle unused toner particles. As a result, the particles collect often on walls and other open spaces, which can impair the clear picture reproduction.

These disadvantages are avoided by the invention. The inventive Process for image development in electrostatic duplicating machines by means of cascading toner particles trickling down, whereby unused toner particles are returned for reuse is characterized in that a developer mixture of carrier granulate and toner particles between two opposite, separate Side walls between an image pickup part and a guide part is fed, wherein therein a perforated zone extends approximately parallel to the latent image and the Prevents the passage of carrier granules while allowing the toner particles to pass through. The picture taking part opposite side wall is electrically charged so that the toner particles pass through the perforated zone and in the development zone, that of the image pickup part and which is bounded by this opposite side wall, form a cloud of toner particles. The cloud of toner particles

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is electrostatically attracted to the latent image, i.e. the image is developed. The opposite of the guide part Sidewall is also electrically charged so that the unused toner particles pass through the perforated zone step and form a cloud of toner particles in a recovery zone through the guide member and the opposite Sidewall is limited. The developer mixture is fed to the recovery zone and mixes with it the cloud of unused toner particles and is therefore reusable.

To carry out this process, a device is used with two spaced apart and one shaft for Feeding of the carrier granulate and toner particles Developer mixture defining side walls, which are arranged at a distance between the guide part and the image receiving part are so that between the image receiving part and a first side wall the development zone and between the guide part and the opposite, second side wall there is the recovery zone, each side wall having one to the latent image approximately parallel, perforated zone, which only lets through toner particles, but no carrier granulate. Furthermore, a device for such charging of the two side walls is provided that initially the first Sidewall is at a higher potential than the second sidewall, so that the toner particles through the perforated Zone in the first sidewall and a cloud of toner particles to develop the latent image in the development zone form, and that after the development of the latent image, the second side wall is at a higher potential than the first side wall so that unused toner particles pass through the perforated zone of the second side wall and form a cloud of toner particles in the recovery zone,

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which mixes with the developer mixture passing through.

For a more detailed explanation, an Aus is in the drawing. management example shown. It shows:

Fig. 1 is a schematic representation of the operation of an electrophotographic. Duplicating machine,

Fig. 2 is an enlarged partial section for. Explanation of those used in the duplicating machine of FIG Development facility and

Fig. 3 is a partially enlarged sectional view of the developing device according to "Fig. 2 for generating a cloud of toner particles....

In Fig. 1 there is an embodiment of an electrophotographic Duplicating machine according to the invention shown. The machine projects an image of the original to be reproduced on a light-sensitive, photoconductive surface and forms on this a latent, electrostatic image. By deposition toner particles on the latent image develop it to form a powder image. The powder picture is then electrostatically transferred to a sheet of paper or other base material. The powder image is then permanently fixed on the base by a suitable melting device.

In the duplicating machine according to FIG. 1, this is photoconductive or image pickup part, a rotatable drum 10 having a photoconductive surface 12. The photoconductive surface 12 consists of an insulating material, for example vitreous selenium. The drum 10 can be by a not shown Turn the drive in the direction of arrow 14. When rotating the Drum 10 in the direction of the arrow passes through its photoconductive surface 12 successively through a series of processing stations.

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First, the photoconductive surface 12 passes a charging station A, in which a corona generator 16 is located transversely to the photo, conductive surface 12 extends. The corona generator 16 charges the drum surface 12 to a relatively high, uniform level Potential·

Thereafter, the drum surface arrives at an exposure station B with an exposure mechanism 18, which generates the charged, exposed photoconductive surface 12 corresponding to the original to be reproduced. The exposure makes the partially discharged photoconductive surface. Other devices can also be used, which are known per se Way to create an image on a usually insulating surface.

After the electrostatic latent image has been recorded on the photoconductive surface 12, the drum 10 rotates on to the development station C, in which toner particles are deposited on this in order to produce a visible image. The developing device 20 generates a powdery cloud of toner particles that are electrostatically attracted to the latent image recorded on the photoconductive surface 12.

The now visible image goes on to transfer station D, where the powdered image is placed on a sheet of final backing material 22, for example paper or the like is transmitted. The base material 22 is located between guide rollers 24 and 26. A second corona generator 28 allows the backing material 22 to adhere electrostatically to the photoconductive surface 12 and transfers the powdery toner image onto the backing 22. The web of backing material 22 is unwound from a supply roll 30 and onto a take-up roll 32 wound.

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After the transfer station and before being wound onto the roll 32, the backing material passes through a fusing station E, in which a melting device 34 heats the powdery image and thereby permanently fixes it on the base material 22.

The last processing station in the direction of rotation of the drum TO (see arrow 14) is the cleaning station G. After each transfer process a rotatably mounted fiber brush 36 contacts the photoconductive one Surface 12 and removes residual toner particles therefrom.

The development unit 20 is shown in detail in FIG. For a clearer illustration of the parts contained therein, the unit 20 is cut perpendicularly. Main components of the The winding unit 20 is the developer housing 38, side walls 48, 50, a guide member 42, a first conveyor 44 and a second conveyor 46. The side walls 48 and 50 are opposite one another at a distance. The first side wall 48 includes a perforated one Zone, i.e., a screen or grid 52, spaced approximately parallel to that on the photoconductive surface recorded electrostatic latent image. The second side wall 50 contains a perforated zone, i.e. a screen or a grid 54. The second side wall 50 lies between the first side wall 52 and the guide part 42. The grid 54 extends approximately parallel to the electrostatic latent recorded on the photoconductive surface 12 Image. The grids 52, 54 can be produced as fine, close-meshed grids made of a suitable conductive material. The opening or mesh size should be selected so that the toner particles pass through without blocking the openings can, while carrier granulate cannot penetrate. Likewise a distortion of the electric field is to be prevented »

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The guide part 42 is preferably made of insulating material, for example "Bakelite ^11" .

A developer mix 56 is placed in the feed chute for image development 62 supplied between the side walls 48 and 50. As the first conveyor 44, a bucket conveyor is provided that the Dispenses developer mixture from a first area 58 in the lower part of developer housing 38 into slot 62. How through Indicated by the arrow 64, the developer mixture 56 trickles down in the shaft 62. A voltage source 66 brings a direct voltage potential of approximately 150 to 300 volts to the Grid 52, the voltage of grid 52 being greater than that of grid 54. When the developer mix 56 in direction If the arrow 64 falls downwards, the toner particles are stripped from the carrier granulate and enter through the grid 52 the development zone 68. In the vicinity of the electrostatic, latent image on the photoconductive surface 12 forms a cloud of toner particles in the development zone 62. The particles are attracted and form a powdery toner image corresponding to the recorded latent image.

After the electrostatic latent image has developed on photoconductive surface 12 (FIG. 2), grid 52 is disconnected from the voltage source. The voltage source 70 applies a direct voltage of approximately 150 to 300 volts to the grid 54, which is thereby electrically charged via the grid 52. At the same time, the second conveyor, a bucket conveyor 46, brings the developer mixture 56 from the lower region 58 of the developer housing 38 into the third, upper region 72, where the developer mixture falls in the direction of the arrow 76 into the recovery zone 74 between the grid 54 and the guide part 42 . When the DC voltage is applied to the grid 54, the unused toner particles pass through this grid into the recovery zone 74, where they are with the

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interacting developer mixture coming down from the conveyor 46. As a result, the remaining, unused toner particles for subsequent reuse in the lower ' Area of the developer housing 38 returned.

The potential at the grids 52 and 54 must be so great that the triboelectric attraction between the carrier granules and the toner particles can be overcome and the toner particles can be moved in the corresponding direction. For example, if the grid 52 is electrically charged via the grid 54 is, the particles move towards the photoconductive surface 12, while when the grid 54 is charged over the Grid 52 move the particles in the direction of the guide member 42. The voltage required therefore depends on the distance between the grids 52 and 54 and on the desired particle acceleration. The voltage sources 66 and 70 load the associated grids 52 and 54 to the correct tension at the correct time. For example, the voltage source 66 charges that Grid 52 during development and is therefore switched off when the voltage source 70 touches the grid 54 during the return of unused toner particles. Instead of two voltage sources you can also use one single voltage source working via a suitable switching device each grid at the right time during the Operation of the machine charges «

Fig. 3 shows in detail the arrangement of grids, guide part and photoconductive surface. The development begins when the developer mixture 56 falls down in the shaft 62 and passes the dtter 52 and 54, which are located opposite one another at a distance. At this time, the DC voltage of the grid 52 is higher than that of the grid 54. This causes the toner particles

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stripped from the carrier granulate and pass through the openings of the grid 52 into the development zone 68. In the development zone 68 comes the cloud of toner powder with the electrostatic, latent image on the photoconductive surface 12 in contact. The electrostatic image attracts the toner particles so that a powdery toner image of the original to be imaged is produced on the photoconductive surface 12. Then the rest of the unused toner particles returned by switching off the grid 52 and the grid 54 to a higher voltage as the grid 52 charges. As a result, the unused migrate Toner particles through the grid 54 into the recovery zone 74. In the recovery zone 74, the unused ones act Toner particles together with the developer mixture coming down there and are stored in the for subsequent reuse Sump or supply of developer housing 38 passed.

The invention thus makes the operation more electrostatographic Duplicating machines by combining the cascade development with the powder cloud development considerably where a cloud of toner particles is created near the photoconductive surface and what is recorded on it electrostatic latent image developed. In addition, the remaining, unused toner particles become later reuse returned to the sump or reservoir of the developer housing.

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Claims (10)

Claims Process for image development in electrostatic duplicating devices by means of cascading toner particles trickling down, with unused toner particles being returned for reuse, characterized in that a developer mixture of carrier granulate and toner particles is fed between two opposite, separate side walls between an image receiving part and a guide part, a perforated part being fed therein Zone extends approximately parallel to the latent image and prevents the passage of carrier granules, while it allows the toner particles to pass, that the side wall opposite the image-receiving part is electrically charged, so that the toner particles pass through the perforated zone and in the development zone, which by the Image receiving part and the opposite side wall is limited to form a cloud of toner particles that the cloud of toner particles is electrostatically attracted by the latent image and there s picture developed _? that the side wall opposite the guide part is electrically charged so that the unused toner particles pass through the perforated zone and form a cloud of toner particles in a recovery zone which is delimited by the guide part and the side wall opposite it, and that the developer mixture is fed to the recovery zone and mixes with the cloud of unused toner particles for subsequent reuse. 2. The method according to claim 1, characterized in that the side wall opposite the image pickup part a direct voltage of approx. 150 to 300 volts across the side wall is charged, which is opposite to the guide part. 30988 2/127 7 ? 2557Α5 3. The method according to Angruch 1, characterized in that the side wall opposite the guide part to a DC voltage of approx. 150 to 300 volts across that of the image pickup part opposite side wall is charged. 4. The method according to claim 1, characterized in that between the image pickup part and the one facing towards the electrostatic, latent image moving into the development zone Cloud of toner particles a relative movement is generated. 5. Device for performing the method according to claims 1 to 4, characterized by two spaced apart opposite and a chute for supplying the developer mixture consisting of carrier granulate and toner particles defining side walls which are arranged at a distance between the guide part and the image pickup part, so that between the image receiving part and a first side wall, the development zone and the recovery zone is present between the guide part and the second, opposite side wall each side wall comprising a perforated zone approximately parallel to the latent image and containing only toner particles, but does not let through any carrier granulate, and through a device for such charging of the two side walls, that initially the first side wall is at a higher potential than the second side wall, so that the toner particles pass through the perforated zone in the first sidewall and develop the latent image in the development zone form a cloud of toner particles, and that after the development of the latent image, the second side wall is at a higher potential than the first side wall, so that unused toner particles through the perfori erte Step zone of the second sidewall and form a cloud of toner particles in the recovery zone, which with the passing through developer mixture mixed. 309882/1277 6. Apparatus according to claim 5 »characterized by a
first conveyor for transporting the developer mix
a first area into a second area and for delivery
into the feed chute and through a second conveyor to the
Transport of the developer mix from the first area to
a third area for discharge into the recovery zone,
where the developer mixture interacts with the cloud of unused toner particles and is returned to the first area with this for subsequent reuse. 7. Device according to claim 6, characterized in that the first side wall is set to an electrical voltage of approx.
150 to 300 volts above that of the second side wall is charged. 8. Apparatus according to claim 6, characterized in 'that the second side wall to a DC voltage of about 150 to 300 volts above that of the first side wall is charged « 9. Apparatus according to claim 6, characterized by means for generating a relative movement between the image recording part and the cloud of toner particles moving towards the latent, electrostatic image in the development zone, 10. Device according to claims 5 to 9, characterized
by a corona generator to the approximately uniform
Charging of the photoconductive surface and through an exposure mechanism, the charged, photoconductive
Surface corresponding to the electrostatic, latent image
selectively discharges an original to be reproduced. 309882/1277 Blank page