DE1797130A1 - Electrophotographic reproduction process - Google Patents

Description

Eastman Kodak Company, Rochester, New York State United States of America

Electrophotographlsohee Beeprodukt ion process

The invention relates to a method of producing one on a photoconductive insulating layer carried by a transparent, electrically conductive carrier layer a fully developed image present on a first carrier, as a latent, electrostatic image on a second carrier which has an electrically conductive carrier layer and an insulating layer carried by this having, the latter being charged and then the two insulating layers placed on top of one another.

In the article "Electrophotography" published in "Focal Press", Chapter 6, pages 87-96 are of various types Described processes for the transfer of latent, electrostatic images. These procedures are called TESI processes designated. In each of the processes described, an electrostatic image is created on the surface of a electrostatic

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trlsohen material, and. either by inducing Charges In the form of a charge pattern on the surface of the dielectric material or through the actual transfer of charges from the surface of the dielectric material to another. With the TESI process No. 3 is based on the electrostatic image on a »xerographisohen Carrier that has been produced by conventional process steps is one with a conductive carrier layer ▼ the charged dielectric film. Then both carriers are earthed. Now there is the potential difference between the conductive supports is zero »the field strength in the air gap in the image area duroh the sum of the potential differences of the positively charged image and the negatively charged dielectric material determined. The image transfer takes place when these benJ & le surfaces are separated. In this way of working * uß Provision must be made that both carriers are at ground potential are placed so that no secondary discharge phenomena occur between the surfaces during the separation,

Ss is known * that a discharge between charged, contacting photoconductive layers occurs, when these are brought into contact or separated from each other because the air between the layers breaks down. These breakdown or discharge phenomena will occur due to the small spacing of the charged photoconductors

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Surfaces and caused by the high field strength. So long the potential differences that exist between surfaces, exist, cannot be reduced or eliminated, the secondary discharge phenomena express themselves occur during the contact of the surfaces or during the separation of the two surfaces during development al8 clear chaos.

The invention is based on the object of creating a method of the type mentioned at the beginning in which the Nögliohkelt secondary discharge circuit is excluded.

In a method, this task is the one mentioned at the beginning Kind according to the invention achieved in that the photoconductive insulating layer of the first carrier is uniform charged and the photoconductive insulating layer of the «wide carrier with an evenly distributed surface charge the same polarity as that of the first carrier is provided, and that after the juxtaposition of the charged Surfaces of both carriers have the photoconductive insulating layer of the second carrier through the first carrier

by means of actinic light a uniform / luminous Source exposed and the potential gradient between the surfaces facing each other both in the image areas al8 also reduced to a large in the background areas which essentially no Entlalungersoheinungen

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in the event of a reduction in capacity. The potential the surface charge depends on the capacity of the respective carrier.

On the facing surfaces of the two carriers, an electrostatic image in accordance with the fully developed and thus visible image formed · As the electrostatic image formed on the surface that touches the original image or is located a short distance away from it the electrostatic image coincides with the visible image with less, if any, loss of sharpness or resolution, giving excellent sharpness of reproduction is achievable. Due to the evenly distributed electrostatic surface charge on both surfaces surfaces have the same polarity and the same potential, secondary discharges are created between them touching surfaces of the two I el! appeared practically impossible when separating these surfaces. The potential gradient between the mutually facing surfaces is in fact hereby both in the image and in the in the background areas reduced to such an extent that no breakdowns can occur during separation. In the exposure substantially neutralized by the photoconductive insulating layer on the second or transparent area Carriers will carry the charges in the light / while they are in the dark or unexposed areas remain unchanged.

The latter areas are the

first vehicle toned areas.

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The invention is at hand in the following description τοπ in the drawings shown examples according to the invention la explained individually.

Show it:

Pig. I a Vertikalsohnitt eohematieoh shown, which has a configuration represented by discharge patterns _r xerographic by two plates whose photo-conductive layers are in close proximity;

Fig. 2 depicts the pig. 1 similar cut, in dea it is shown how they form discharge patterns, when the electrically conductive support layer of one of the xerographic plates is grounded;

3 shows a section similar to FIG. 1, in which it is shown is how sioh the field lines form when a bias is applied to the electrically conductive Carrier layer of one of the xerographic plates is applied without any lighting he follows·

F.lg. k any of the pig. Section similar to 1, in which the photoconductive layer of each xerographic plate has a surface charge of the same polarity

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and has essentially the same potential, there are no external electric fields that could form a discharge pattern;

PIg. 5 and 6 each have an eohematically illustrated vertical section a xerographic plate bearing a fully developed and visible image, and a xerographic plate for receiving a copy, FIG. 5 showing the charge distribution the lighting and in FIG. 6 the charge distribution as a function of the visible image after the lighting is shown;

7 shows an arrangement of a device, shown mechanically to carry out the process in continuous operation.

Before the description of the method according to the invention for its better understanding, discusses the factors and phenomena that this procedure is intended to eliminate. It has already been mentioned that the problem of secondary drainage occurs when a photoconductor is used Copy material bearing a surface charge, a photoconductive original is touched or separated from it. The mode of action more differently to the electrical conductive carrier layer of applied biases wix-d now In described in the following examples.

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Example I (Pig. 1)

A first xerographic plate 10 ″ is a photoconductive one Insulating layer 11, which is supported by an electrically conductive carrier layer 12. Einffrweit xero graph-like plate 13 has a photoconductive layer and an electrically conductive carrier layer 15.

The surface of the Sohloht I ^ was initially marked with a negative Surface charge of 1,000 volts provided. Then the photoconductive layer 14- of the plate 13 in Contact with the photoconductive insulating layer 11 of the Plate 10 brought. The electrically conductive carrier layer of each of the two plates was intentionally left out grounded, u »a charge shift in the carrier layer to allow. There was no exposure. Since the carrier layer 12 is electrically conductive, it carries both positive and negative charges that can move freely. Becomes the charged surface of the sole l * t brought into contact with the layer 11, then some of the positive charges in the support layer 12 due to the induced electric field towards the negative ones Charges attracted to the layer 1A. This charge personification As a result, some of the negative charges are in the support layer 12 and some of the positive charges in the carrier layer 15 are drawn to the outer surface of their corresponding layers. Arrows 16 indicate the «electric field in those areas

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BATH ORIGINAL

exists between layers 11 and 14 * in which induced charges are present. Secondary discharges occur in these areas. Haoh separating the Plate 13 from plate 10 and developing each of the Plates old a liquid developer with the use of a counter electrode one can namely determine that Discharge clusters on the surface of the photoconductive Layers 11 and 14- are visible. One in the same way Loaded and developed control plate, but not that is brought into contact with another surface, in contrast, shows a uniform distribution of the Toner particles without any pattern.

Example II (Fig. 2)

A first xerographic plate 20 consists of a grounded, electrically conductive carrier layer 21 and a photoconductive layer 22. A second xerographic plate 23 has an electrically conductive carrier layer Zk and a photoconductive layer 25.

The surface layer 25 was negative Provided a surface charge of 1,000 volts and then brought into contact with the surface of the layer 22. Haoh Separation of the surfaces and after development of the two plates 20 and 23 were again discharge patterns on the Surfaces of layers 22 and 25 visible.

1098 U / 1786 BAD original

As in Example I, arrows 26 indicate the electric field exists between the photoconductive layers 22 and 25, and the areas in which secondary discharges are due of the induced charges arise. In this case, however, the negative charges of the layer 21 flow due to the Ground this layer off.

Example III (Fig. 3)

A first xerographic plate 30 has a photoconductive curve Layer 31, which is carried by an electrically conductive carrier layer 32. This carrier layer 32 was with charged with a negative bias of 1,000 volts. A second xerographic plate 33 has an electrically conductive one Carrier layer 3 ^ and a photoconductive layer 35 on. The surface of this layer was provided with a negative surface charge of 1,000 volts and with the layer 31 of the xerographic plate 30 brought into contact. To separating and subsequently developing the plates 30 and 33, no discharge patterns could be observed on the surfaces of layers 31 and 35. It can be assumed that by biasing the plate 30 to a potential

and size like that of the plate 33 with the same polarity / any electric field that exist between the photoconductive layers 31 and 35 could be neutralized. In this way the plates can be separated from one another without any

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A shift in the charge or secondary discharge phenomena occur, even when a bias voltage is applied to the carrier layer 32, however, secondary discharge phenomena occur with a subsequent illumination through the carrier layer and a subsequent separation of the layers 1 and 35.

Example IV (Flg. Fr)

In this example, a first xerographic plate was used for one electrically conductive carrier layer 41 and one photoconductive Has layer fr2 and a second xerographic plate fr3, which consists of an electrically conductive carrier layer frfr and a photoconductive layer fr5, provided with a negative surface charge of 1,000 volts. In connection the plates fro and fr3 were then attached according to the invention arranged so that their photoconductive layers faced each other. After separating the panels were these developed, mbe! no charge patterns visible on them the plate became fr3 with a negative surface charge of 500 volts and the plate fro with a negative surface charge of 1,000 volts and were both In Facing one another as described above, the developed images then showed slight secondary discharge phenomena which were less than when the layer fr2 was not charged, but greater than when the two layers were equally charged.

1 0 9M 1 Λ / 1 76 6

Example V

In the exemplary embodiment according to the invention shown in FIGS. 5 and 6, essentially no secondary discharge phenomena occur. An original or first xerographic plate 50, which has a photoconductive layer 51 and a carrier layer 52 carrying it, carried a toner image 53. This image was produced by known xerographic processes and was fully visible. The copying material was a xerographic plate 5 bits of a photoconductive screw 55 and an electrically conductive carrier layer 56. The photoconductive layers 51 and 55 received a negative surface charge of 1,000 volts and were then brought into contact with one another. The electrically conductive carrier layer 52 awS is transparent "in order to allow uniform illumination of the original 50 cu". With such an illumination by the original Hindu light, the light falling on the photoconductive layer 55 conducts the exposed areas, so that the charges in these areas are essentially neutralized. Since the toner image 53 prevents light from reaching the opposite areas of the surface of the shaft 55 , the charges in the image surfaces remain unchanged. In the case of separation, electric fields only exist in the picture areas; However, they do not break down if the plates 50 and

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separated from each other. The electrostatic latent image on the original, i.e. on the surface of the toner, is formed due to the thickness of the toner. With suitable charging conditions, the two latent electrostatic Images match exactlyJlIe size of the charge, to which the original should be charged is a function of the different dielectric constants and the Thickness of the photoconductive layers and the thickness of the toner deposit on the template, whereby the secondary discharge phenomena are caused by the capacitive arrangement of the photoconductive elements Layers, through the air gap between the photoconductive Layers and caused by the electrically conductive carrier layers.

In Fig. 7 a device is shown with echematisoh which the process according to the invention can be carried out continuously.

A band-shaped original 70 made of a xerographic material carries visible images that are separated from one another in the longitudinal direction. A copy material 71 consists of a xerographic lens Material with a photoconductive layer which is supported by an electrically conductive carrier layer.

Original and copy material are connected to one through a grounded Pair of rollers 72, 73 brought into contact with each other specific point. The image surface of the template is thereby

1 0 9 8 U / 1 7 6 6 ORIQtNAt INSPECTED

oriented in such a way that β ie comes into contact with the photoconductive layer of the copying material. A corona discharge line 74 is arranged in front of the pair of bolts 72, 73 between the original and the copy material and is connected to a DC voltage source 75 . This voltage source can apply either a positive or negative voltage to the corona wire 76, which charges the original and copy material either positively or negatively, as required. φ One or a pair of separate corona shields 77 that are grounded can be used to direct the stream of ions onto the surface of the original and copy material. The copy material is exposed between the pair of rollers 72 and 73 and a pair of bolts 78, 79. A lamp 80, which interacts with a condenser-lens system 81, serves as the light source. The copy material 71 and the original 70 are separated from one another again in the pair of rollers 78 and 79. Danaoh, the original is wound onto a roll 82 while the copy material is passed through a developing device. 83 and a baked-in device 8k is fed back and then wound onto a boll 85.

It will be apparent that the image on the copy material 71 will be transferred to another after development in a known manner Material can be transferred to obtain a hard copy. In this case, the copy material 71 would follow then wound onto the roll 85 and the transfer material be passed through the burn-in device 84. if

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the original 70 is a xerographic material if it bears visible images, then it must be transparent, have an electrically conductive carrier layer so that lighting through the material can be achieved, whereby the necessary neutralization of the charges in the background areas is achieved.

ORKälNAL INSPECTED 109814 / 1.76-6 C

Claims (5)

Claims A method for reproducing a fully developed image present on a photoconductive, insulating layer of a first carrier carried by a transparent, electrically conductive carrier layer, as a latent, electrostatic image on a second carrier which has an electrically conductive carrier layer and an insulating layer carried by the latter, wherein The latter are charged and the two insulating layers are then placed on top of one another, characterized in that the photoconductive insulating layer (11, 22, 31, 42, 51) of the first carrier (10, 20, 30, 40, 50) is charged smoothly and the photoconductive Insulating layer (14-, 25, 35, 45, 55) of the second carrier »(13, 23, 33, 43, 54) with an evenly distributed surface! a <1 »mg of the same polarity as that of the first carrier, and that after the surfaces of the two carriers have been placed against one another, the photoconductive insulating layer of the second carrier is exposed through the first carrier to a means of actinic light from a uniformly illuminating source and that The potential gradient between the mutually facing surfaces both in the image areas and in the background areas is changed to a size which essentially does not allow any discharge in the event of a reduction in capacity. BAD ORIGINAL 1098 U / 1766 2) Method according to claim 1, characterized in that the two carriers (10, 20, 30, 40, 50 and 13, 23, 33 ² Ut 5 * 0 are separated from each other after exposure. 3) Method according to claim 1 or 2, characterized in that the generated on the second carrier (13, 23, 33, 43, 54) electrostatic image is developed xerographically. 4) Method according to one of claims 1 to 3 »characterized in that that on the respective photoconductive insulating layer of the two carriers a uniformly distributed negative electrostatic surface charge of about 200 volts to 1,500 c 5) Method according to one of claims 1 to 3 »characterized in that that on the respective photoconductive insulating layer of the two carriers an evenly distributed positive electrostatic surface charge of about 200 volts to 1,500 volts is brought. BAD ORIGINAL 1Oi- 'u / 1766 Blank page