DE2161850A1 - Electrostatic latent image developing device - Google Patents

Description

Rochester, NY 14 605
V.St.A.

Electrostatic latent image developing device

The invention relates to an electrostatic developing device latent images, in which a two-component developer is applied to a recording medium provided with a latent image is cascaded and an electrically conductive development electrode is arranged in the development zone.

In the electrophotographic process, as described in U.S. Patent 2 297 691 is known, becomes a record carrier with a layer of a photoconductive insulating material on a conductive base to generate latent electrostatic Images used. During the normal implementation of the method, the recording medium is on its surface electrostatically charged uniformly and then irradiated with a light image of an image to be reproduced, whereby the charge in the exposed parts of the surface is diverted. The non-discharged areas of the layer thus generate a electrostatic charge pattern, the distribution of which corresponds to that of the original image.

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The electrostatic latent image can then be developed by treating it with a finely divided electrostatic attractant Material, for example with a powder, is brought into contact. The powder is in the image area parts by the electrostatic Charges bound on the layer. Most of the powder is deposited in the areas of greatest charge density. Where the When the charge is weakest, little or no powder is deposited. This creates a powder image that corresponds to the image to be reproduced. The powder can then be applied to a A sheet of paper or another surface can be transferred and fixed on this as a permanent image.

It is known that the development of latent electrostatic images, particularly the cascading development, can be carried out by a development electrode be improved. One such method is described in U.S. Patent 2,952 24-1.

In this process, a conductive member is placed in close proximity to the electrostatic latent image to be developed arranged. If this electrode carries earth potential, it causes the electric field lines to run continuously in the toned areas of the latent image at right angles out of the recording medium, so that the charged toner particles of the Developer mixture in the middle areas of this throughout Areas to be tinted are also deposited, which is not the case in the absence of a development electrode, since No electric field between the central areas of the surfaces to be tinted continuously and the surfaces adjacent to them exists. The development electrode reduces the HaIo effect, which can be generated by the fact that charged toner particles develop only the edges of the image areas to be continuously tinted, where the charge gradients are most pronounced.

US Pat. No. 2,952,241 also describes the electrical tensioning of the electrode with a polarity that corresponds to the polarity of the charge of the recording medium matches / This

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a potential is used that is slightly higher than the potential in the surface parts that do not belong to the image or in the Background surfaces is. This allows the benefits of the grounded electrode to be retained and great sound throughout Areas to be developed. With the biased electrode, however, an additional benefit can be obtained since the toner particles, which are charged opposite to the image areas and the background areas have a greater affinity for the electrode than for the background areas of the latent image so that toner deposition in such areas is minimized will. This results in better images and copies.

It is easy to see that the biased electrode works better than a grounded electrode because of all the advantages of the grounded electrode Electrode and, in addition, another advantage can be achieved. However, the biased electrodes also have certain Disadvantages that consist in the fact that with an electrode charge which is less than the charge of the background areas of the latent Image is, the additional benefit does not occur. However, the charge on the electrode is more than slightly stronger than the charge of the background areas on the recording medium, it can have an effect on the charged toner similar to that of the image area parts exercise.

The object of the invention is to provide a developing device to create, in which the development electrode automatically by a small amount stronger than the background areas of the image to be developed remains loaded.

A developing device of the type mentioned is designed according to the invention to achieve this object in such a way that the development electrode is arranged at a distance of less than x 5 mm from the recording medium and opposite all other electrically conductive elements in their environment is electrically isolated.

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Advantageously, the developing electrode can be used in a developing device be arranged in which the recording medium in the upward direction against the flow direction of the cascading Developer material is moved. The electrode is electrically isolated from its surroundings, so that it is a ground and the recording medium leads sliding potential.

The invention is described below with reference to an embodiment shown in the figures. Show it:

1 is a side view of a continuously and automatically operating electrophotographic reproduction machine, in which a developing device operating according to the invention is arranged, and

FIG. 2 is an enlarged side view of the development zone of FIG device shown in FIG.

In Fig. 1 there is an embodiment of the invention within an automatic electrophotographic reproduction machine shown. This contains a xerographic recording medium 10 in the form of a drum. The record carrier has a photoconductive layer to be irradiated a conductive base and is in the machine frame in the direction of arrow shown rotatably mounted. As a result of the rotation, its surface is successively applied to several electrophotographic Process stations moved past. For a better understanding of the invention, these process stations are in Description of the movement range of the recording medium with regard to its function:

A uniform electrostatic charge is applied to the photoconductive layer at a charging station A, At an exposure station B, a light or radiation image of the image to be reproduced is applied to the surface of the recording medium projected to the charge in the irradiated tone

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Derive areas and thereby generate a latent electrostatic image of the image to be reproduced. At a development station C, a xerographic developer is used with toner particles having an electrostatic charge opposite to that of the electrostatic latent image cascaded over the surface of the recording medium, whereby the toner particles adhere to the latent electrostatic image and generate a toner image having a configuration of the image to be reproduced.

At a transfer station D, the toner image is electrostatically transferred from the surface of the recording medium to an image medium transfer.

At a drum cleaning and unloading station E, the The surface of the recording medium is brushed off to remove residual toner particles that are still adhering and with a relatively bright light source illuminated in order to achieve a practically complete dissipation of residual electrostatic charges .

A bucket conveyor 14 is provided at development station C, the developer continuously from a lower part 16 of the development housing 18 into the raised part 20 conveyed, from where the developer falls by gravity into the development zone 22.

The developer material is poured into the development zone via input dumps 24 and 26 which are electrically connected to voltage sources V1 and V2. An insulating strip 28 insulates the chute 24 opposite the electrode 30. The developer is then by gravity in a smooth flow through the development zone 22, which is formed by the volume between the recording medium and the development electrode is. In the development zone, the developer is brought into contact with the surface of the recording medium in order to to generate the latent image, after which it is through stripping surfaces 32 and 34 removed from the drum surface again and in the

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lower storage area. 16 is traced back from where he came from is directed back into the development cycle.

The surface of the recording medium becomes in the development zone moved continuously in an upward direction against the flow of the developer in order to effect the development. A toner input device 36 is used to input additional amounts of toner into the developer mixture in order to get through the Replace used toner for image development.

The development electrode 30 extends across the width of the recording drum and the length of the development zone 22 and extends from the entry chute 24 to a point below the horizontal diameter plane of the drum, as shown in FIG. This is how the Development zone by the shape of the electrode so wide that in the absence of the electrode the developer normally would fall off the drum sooner due to its gravity.

The development electrode is made of electrically conductive material and is secured with insulating members 38. For this For example, commercially available circuit cards can be used, which are arranged on each side of the electrode. On these For example, the electrode is provided by an insulating adhesive or by bolt elements 40, as shown in FIG. 2 is attached.

The entire surface of the development electrode is preferably made smooth in the area of the development zone, around the To keep turbulence of the developer material to a minimum. It could be increased by irregularities in the electrode surface. As with most electrodes, the development electrode described here should be as close as possible to the surface of the Be arranged recording medium, but without disturbing the flow of the developer. It has been shown that a

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constant distance of less than 5 mm, preferably of about 1.5 mm between the drum and the developing electrode is advantageous is. This distance is particularly suitable for carrier particles of the developer with a size of approximately 0.25 mm. Through this there is a distance between the electrode and the recording medium which corresponds to approximately 6 particle diameters.

In order for the developing electrode according to the invention to work properly, it should not come into contact with an electrically earthed element. Furthermore, it should not be connected to an electric Be connected to the voltage source. It can be seen that such a development electrode has a positive effect on its surroundings electrically sliding state. However, a certain amount of charge can come from the chute 24 via the dielectric or insulating strips 28 and generate a low potential on the electrically sliding electrode 30.

Due to the special function of the development electrode, an electrical charge is generated on the recording medium moves the development zone close to the development electrode becomes, a charge of the same polarity on the electrode. The charge induced on the developing electrode is a Function of the total amount of electrical charge in its area or within the development zone at a given point in time, The electric charge on one sheet of the development electrode is the same as that on another Area of the electrode.

The entire development zone can be viewed as a capacitor in which a change in the charge of one of the elements, namely the recording medium, a change in the charge in the other element, namely the electrode, is generated. It is recognizable, that the entire system regulates itself in such a way that a change in the charging current for the recording medium before the irradiation or the power of the irradiation lamp, the ability of the development electrode to work normally,

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is not affected, since the electrode is only charged as much as it is due to the charge of the image to be developed is given.

Under normal operation within the parameters described above, it has been found that the development electrode is charged quickly to the optimum potential slightly above the potential of the background areas of the recording medium. It therefore works like a pre-stressed electrode for developing surfaces to be tinted throughout and reaches this State within the time in which a first electrostatic latent image passes through the development zone at the beginning of a Copy cycle or a working day.

A successful test with a developing device according to the invention was that a recording medium on Approx. 750 volts positively charged and through light in the form of a pattern to approx. 700 volts positively in the image areas and 200 volts was positively discharged in the background areas. With a potential of 1200 volts positive at the chute 24 the development electrode had a sliding potential of approx. 350 volts positive during image development, this fluctuated between 250 and 450 volts positive.

The "sliding" development electrode is for commercial use Application well suited because it has the advantages of normal development electrodes and also an automatic one Allows regulation and adjustment to the picture to be developed in each case. This is done without additional pre-tensioning within the development system.

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Claims (3)

Claims 1. Electrostatic latent image developing device; in which a two-component developer is cascaded over a recording medium provided with a latent image and an electrically conductive development electrode in the development zone is arranged, characterized in that the development electrode (30) at a distance of less than 5 mm to the recording medium (10) and opposite all other electrically conductive elements is electrically isolated from its surroundings. 2. Development device according to claim 1, characterized in that that an insulating fastening element (28) is provided, which the transition of an electrical fault current by an electrically biased element (24) adjacent to the development electrode (30). 3. Development device according to claim 2, characterized in that that the electrically biased element (24) is an input chute, the entry of the two-component developer into the development zone between development electrode (30) and recording medium (10).