DE1522695C3 - Process for the production of charge images on insulating sheets - Google Patents

Description

3 ° The invention relates to a method of manufacture

of charge images on insulating sheets, in which an insulating sheet covers the entire surface with a Contact image plate carrying charge image and progressing from this from one end to the other is lifted off, with one in the area of the lifting line on the free rear side of the insulating sheet electrically conductive role is unrolled.

It is known that with the help of electrostatic devices on the surface of certain photoconductive materials Images can be produced and developed, which then from there onto a sheet be transmitted. In the basic electrophotographic process as described in U.S. Patent 22 97 691, a uniform charge is created on a photoconductive layer generated, and the layer is then imagewise exposed, creating in the areas of the layer exposed to light are exposed, a charge equalization takes place. The latent electrostatic image formed on the layer corresponds to the shape of the light and shadow pattern in the image. The electrostatic latent image can also can be generated by charging a plate according to the shape of the image. The image is made by applying of finely divided developer material, which contains image powder, so-called "toner", and carrier material the image layer made visible. The powdery developer material is normally used by the still Charge-bearing areas of the layer are attracted, creating a latent electrostatic image corresponding dust pattern arises. The dust pattern can be removed by placing a sheet of paper, such as paper, on the Dust pattern and charging are transferred to the back of the paper. This is how the powder adheres on the paper and can be removed with this. The dust pattern can be evaporated by treatment with Preserved by solvents or by baking.

Very good copies can be made using the procedure described, and it becomes very common applied. This method is particularly useful for making one or a few copies of one certain document. The relatively slow speed of the process and the fact that the successive copies made of a document are all equally expensive, makes this process for the production of large numbers of copies of a single document is not very suitable. the photoconductive layer must be charged, exposed and developed, the image must be transferred, and the photoconductive layer must be cleaned for each copy to be made. Therefore it is desirable to simplify the process of making multiple copies of a single document.

The photoconductive layer is, as it is with relatively highly abrasive image powder carrier grains in Contact comes, heavily worn and must after each exposure process of remaining image powder getting cleaned. This limits the choice of materials for use as photoconductive materials on those with a hard, tough and abrasion-resistant surface. Therefore, vitreous selenium became the Commercial standard material for reusable electrophotographic / aphic plates. With help of selenium plates "many thousands of copies can be made until they are worn out. Others are known photoconductive materials, such as compounds of organic and inorganic photoconductive pigments, organic photoconductive materials and vitreous lacquer plates have many desirable properties, z. B. Panchromatic and great photographic sensitivity. However, they are for reusable Plate systems are not suitable because their surface is not sufficiently tough and they run through Wear and tear become sensitive to moisture. There is therefore a need for an imaging method which the photoconductive layer is not abraded.

The so-called "intermediate layer" development is described in US Pat. No. 2,297,691. Included the abrasion of the electrophotographic plate is avoided by removing a sheet, such as paper, is placed on the image plate bearing the electrostatic latent image so that it contacts it, and that Image powder is then applied to the back of the sheet and fixed there. There is therefore no Contact of the abrasive image powder with the image plate, and there is no cleaning of the image plate from remaining image powder required. However, this method is very sensitive to moisture. If the relative humidity is noticeably above 10%, the electrostatic field does not apply to the Arrangement of the picture powder in picture form necessary time through the paper. The procedure, the sheet Drying paper right before use has the disadvantage that the selenium plate is damaged because the Contact of the plate with hot paper leads to a crystallization of selenium and its specific properties electrical resistance decreased. Furthermore, drying the paper takes time and energy.

Another method of developing latent electrostatic images without touching the photoconductive ones Surface with developer material was for example by Carlson in the US patent 29 82 647 specified.

In this process, a uniformly charged

brought a sheet of insulating material to the photoconductive surface bearing the electrostatic image. If that charged sheet of insulating material is lifted from the photoconductive layer, a "field discharge" occurs A process by which a charge is transferred to the sheet of insulating material in accordance with the original electrostatic latent image occurs on the photoconductive layer. That on the sheet The charge image created by the insulating material can then be developed using conventional electrophotographic equipment will. This method is for making copies without touching the photoconductive surface suitable with developer material. The field discharge destroys the latent image on the photoconductive one Surface almost completely and prevents its reuse. The sheet must also be made of insulating material have very low conductivity. If paper is used, it must be in an environment with 10% relative humidity. Establishing and maintaining this very dry state requires expensive and complicated burning, drying and loading processes.

Another method of developing latent electrostatic images without touching the photoconductor with developer material is disclosed by Hall in US Pat. No. 3,084,061. In this procedure, creates an electrostatic latent image on a photoconductive surface. On the photoconductive Surface is placed a sheet of insulating material, and ^ uf - ~ a uniform potential is generated on the rear side, for example by corona discharge. Because of the original charge on the photoconductive surface due to the insulating material A charge induction occurs on the front surface of the field extending through it, so that the on the front surface of the insulating material is changed according to the shape of the image. For example, if a positive image was created on the photoconductive surface and the front Surface of the insulating material has been charged by a uniform negative potential, so is the negative charge in the area of the original positive image larger. If the insulation material is from The photoconductive surface is lifted off, because of the charge transfer from the photoconductive surface Layer to the lower surface of the insulating material in the charged areas a breakdown through air. The insulating material can then be used to produce an image corresponding to the original developed according to standard procedures. will. The inevitable breakthrough by air, by the at During the separation, charge is transferred to the lower surface of the insulating material, it deteriorates Charge pattern on the photoconductive layer, eliminating the possibility of the original pattern making additional copies is limited. Furthermore, this method requires that the transfer sheet very well insulated. This poses problems in production and maintenance for paper and others similar materials used in this process required extremely low relative Humidity.

From US Patent 31 02 045 a method for electrostatic printing of Tissues become known in which an electrostatic latent charge image on a in the usual way photoconductive layer is produced. Then this photoconductive layer, which is the electrostatic latent charge image is placed on the fabric to be printed and while the fabric is in contact with it the photoconductive layer is located, becomes like the side of the fabric facing away from the photoconductive layer developed with a developer material. Then the fabric is removed from the photoconductive layer lifted off and the developer material firmly bonded to the fabric. The goodness of the developed image depends essentially on how much the electrostatic latent charge image sways at all the tissue is effective through it. Overall, the process is very dependent on moisture.

From the German patent specification 9 70 271 there is already a method for the transmission of electrostatic Images are known in which an electrostatic latent layer is usually present on a photoconductive layer Charge image is produced. On the photoconductive layer carrying the latent charge image then an insulating sheet is applied and thereby progressively removed from the photoconductive layer again lifted that along the lift-off line on the back of the insulating sheet one electrically leading role is unrolled. During the lifting process, between the electrically conductive roller and The photoconductive layer generates a high electric field, thereby creating an image-wise transfer of electrical Charges between the photoconductive layer and the insulating sheet in egg / ier by the applied "Field takes place in a certain direction. That way on the The charge image generated by the insulating sheet can then be developed without the photoconductive layer comes into contact with developing material. When transferring charges between the photoconductive The layer and the insulating sheet will retain the original electrostatic latent charge image changed significantly, so that not several uniformly good copies of one and the same electrostatic latent charge image can be generated.

The present invention is therefore based on the object of providing a method of the type mentioned at the outset Specify the type with which a very large number of copies are placed one after the other on the optical disc Sheets can be made.

This object is achieved according to the invention in that for the production of several charge images from one single charge image of an electrically conductive role at a potential of the polarity and size of the Background potential of the primary charge image is held or grounded.

By the method according to the invention, a direct contact of the developing material with the photoconductive layer prevented, so that this layer is not rubbed off by the developing material can occur. The photoconductive layers can therefore be used again and again without significant wear be used. Furthermore, by the method according to the invention on the sheet only one dem original electrostatic latent charge image induced corresponding charge image without during the process of lifting the sheet off the photoconductive layer, a charge transfer occurs between these layers takes place. As a result, neither the charge image remaining on the optical disc nor the charge image induced on the sheet by the lifting of the sheet from the image plate is disadvantageous influenced. Any number of copies of a single electrostatic latent charge image can therefore be made on the image plate on different sheets

getting produced. The number of copies that can be produced without any appreciable loss of quality is thereby solely through the charge reduction as a result of charge equalization within the layer carrying the charge image limited to the image plate.

After the sheet is lifted off the image plate, the sheet is charged by induction in the same pattern (but with opposite polarity) as the electrostatic latent image on the image plate. Since the material of the sheet is mostly slightly conductive, the electrostatic latent image is induced more in the sheet than on the sheet, which would be the case if the sheet were a complete insulator. The induced image should advantageously be developed at the same time as it is lifted off the image plate. However, it can also be developed at any time before the induced potential has subsided, but with a somewhat lower blackening and sharpness. A second sheet can then be placed on the electrostatic latent image bearing image plate and the second sheet peeled off and developed. The latent electrostatic charge image on the image plate is not influenced by these processes. Therefore, before the electrostatic latent image largely subsides, a large number of copies can be made. The sheet on which a corresponding charge image is induced consists preferably of a material with a specific resistance * in the range from 10 ⁷ to 10 ¹⁴ , preferably in the range from 10 ⁹ to 10 ¹² ohm · cm. Furthermore, it has been found to be useful to lift the sheet off the image plate at a speed of between 5 and 100 cm per second, so that satisfactory images are produced. The sheets are preferably lifted and developed at about 37.5 cm per second, since it has been found that at this rate the ratio of image quality to the speed at which the copies are produced is an optimum.

For optimal image density and sharpness, the induced electrostatic latent image should be in the sheet be developed within the "cooldown" of the material used. This cooldown may apply to the leaves used, can be determined empirically. Are for example with the help of corona devices positive and negative charges placed on opposite sides of the sheets, order later to be developed, the potential difference increases according to the equation

AV ₁ = AV ₀ Q- -

from, where τ is the empirically determined "decay time" constant. In the time τ becomes

AV ₁ =

AV _n

55

(e is the base of the natural logarithm; about 2.71823). In this equation, V _{1 is} the potential difference after time t, and Δ V ₀ is the potential difference generated at the beginning. If, therefore, an induced image is developed within a time t which is less than τ , the potential difference is at least 40% of the originally induced potential. It has been found that consistently good image quality is obtained if each copy is developed within this time, the "decay time" of the material.

The electrostatic latent image bearing layer may be made of any suitable material capable of holding an electrostatic charge for a time sufficient to produce the desired number of copies. The layer can for example consist of glass or a resin or an ethyl methacrylate polymer. An electrostatic charge in the form of an image, for example by corona discharge with a stencil, can be applied to such a surface. Although the charge disappears according to the waste characteristics of the material, the charge remains for a sufficient time to make a plurality of copies by the method of the present invention. Alternatively, the electrostatic latent image can be formed on a photoconductive layer as described by Carlson in US Pat. No. 2,297,691. When such material is used, the surface of the layer is uniformly charged in the dark, such as by corona discharge, and the surface is then exposed to the light-shadow image. Because of the photoconductive properties of the layer, the charge disappears in the areas exposed to the light. The charge is retained in the unexposed areas. This charge disappears over time, according to the dark decay characteristics of the material. However, the charge is retained long enough to produce a plurality of copies by the method according to the invention. Typical photoconductive materials which are suitable as layers carrying latent electrostatic images are vitreous selenium, sulfur, anthracene, photoconductive inorganic pigments such as zinc oxide or lead oxide in neutral connection with resins, photoconductive organic pigments in neutral connection with resins, homogeneous layers of photoconductive organic material and charge transferring compositions of Lewis acid and aromatic resins. The insulating sheet, which is charged by induction according to the shape of the image and on which a visible image is then formed, can be selected from a large number of materials. The sheet is required to have a resistivity between 10 ⁷ ohm-cm and 10 ¹⁴ OhITi-cm. It is advantageous if the specific resistance is within this range between 10 ⁹ ohm · cm and 10 ¹² ohm · cm. Paper is a particularly suitable and desirable material because, with the usual relative humidity between 75% and 5%, it has a conductivity within the desired range, is cheap and is always available.

In the following, the invention will be described in more detail with reference to FIGS. 1 to 5 of the drawing will be explained.

F i g. 1 shows a photoconductive plate 1, which consists of a conductive support 2 on which one Layer of a photoconductor 3 is applied. The photoconductor 3 has a latent on its surface positive electrostatic image, which is indicated by positive charge symbol 4. According to the positive charge 4, there is a negative charge on the contact surface of the layer carrier and photoconductor Charge 5. The electrostatic latent image can be formed by conventional methods. The surface of the photoconductor can for example be uniformly charged and then exposed imagewise. The The charge pattern can also be generated with the aid of a template. Various methods of manufacturing

Development of latent electrostatic images are described in US Pat. No. 2,297,691.

Fig. 2 shows a sheet 6 on the surface of the photoconductor 3. The sheet can be made of any material with a specific resistance of about 10 ¹⁰ Ωcm. Typical such materials are many types of paper, cellophane, acetyl cellulose, etc. As can be seen in FIG. 2, a charge pattern 7 is induced in accordance with the original image 4. As indicated in FIG. 2, the total amount of negative charge 5 is on the contact surface of the layer carrier and photoconductor and the amount of induced negative charge 7 taken together equal to the amount of original positive charge 4.

As in Fig. 3 shown, the charge when the sheet 6 is peeled off the photoconductor 3, while the upper surface of the sheet is grounded by a roller 8, automatically separated. To be uniform To achieve grounding, it is advantageous to place the grounded roller 8 above the upper surface of the Sheet 6 to roll. Instead of grounding the role, it can also be at the potential of the exposed areas of the Photoconductor 3 are held. This potential is i. a. less than 100 V. This is opposite to the simple one Grounding the roll 8 is preferable as you get a developed image with better contrasts and less unwanted electroscopic developing powder in underground areas. J

Ground the top surface of the leaf odeffast to ground and develop the induced electrostatic latent image while the top surface of the When the leaf touches a conductive device, essential steps are to maintain its original state electrostatic latent image on photoconductor 3. As in FIG. 3 can be seen, form the grounded role 8 and the base 2 a way over which the induced in the sheet 6 potential can be balanced without that in the resulting gap a breakdown by air, for example from the original picture 4 to the induced one Image 7, done As you can see, the charge pattern and the photoconductor return after lifting off of the sheet in the original in FIG. 1. Therefore, the induced charge of the Sheet 6 has no detrimental effect on the positive image on the photoconductor 3. Many additional sheets Carrier material can be charged one after the other by induction. The number of sheets to be charged is only limited by the time in which the dark decay effects a charge equalization on the photoconductor

In FIG. Example shown in Figure 2 is the negative charge that is the positive charge on photoconductor 3 equalizes than in the contact area between the substrate and photoconductor and in the insulating sheet straight shown the same size This is not always the FaIL It is L a. desirable to have a larger amount of charge in the Sheet than to have in the contact area between the layer carrier and the photoconductor. If the sheet of paper, for example, is on the photoconductive layer is brought, it does not contact the photoconductive layer uniformly. the The contact between the sheet and the photoconductive layer is punctiform. Between these points of contact there are different distances between the two surfaces. These different distances These are shown in the figures as a continuous mean distance between sheet 6 and layer 3 indicates that the contact is in many places. The charge density in the sheet versus that in the The contact area between the substrate and the photoconductor is proportional to the size of the capacitance of the middle Gap between sheet and photoconductor and the size of the capacity of the photoconductive layer itself Therefore, the induced charge density in the sheet can be reduced by reducing the distance between the sheet and Photoconductor and / or increased by reducing the effective capacity of the photoconductive layer. The increase in the charge density in the sheet improves the developing strength without disadvantageous Consequences because the original charge density in the contact layer between the base and the photoconductor is automatic is restored when the sheet is peeled from the photoconductive surface

F i g. 4 and 5 show two examples of development methods for developing the induced in sheet 6 electrostatic latent image. The principle shown in FIG. The development method shown in FIG. 4 uses a engraved roll 9, which has very small notches lying close to one another on its surface Process for developing an electrostatic image is detailed in U.S. Patent 3,084,043 Described a ink from the container 10 is painted with the help of the wick 11 on the engraved roller. the Ink fills the notches in the surface of the roller. The doctor blade 12 removes excess ink from the Web between the notches and bring them back into the container. When sheet 6 from photoconductor 3

- is lifted, it comes against the rotatable and engraved scroll. Ink from the notches is attracted by the charge in the form of an image, thereby reducing the applied charge Ink on the sheet creates a visible image While in this embodiment the upper As the surface of the sheet is developed, one could also see the negative charge pattern from the lower one Develop the surface of the lifted sheet. The latter method is more sensitive to Moisture because the time required compared to the previous process in which the development takes place simultaneously with the field generation by taking off is relatively long

When the sheet is lifted off the photoconductor 3, it comes against the conductive roller 8, in which a positive charge in the form of an image is induced. The capacitive resistance of the roller 8 prevents the negative charge from being discharged through air ionization towards the photoconductive surface. In the exemplary embodiment according to FIG. 5, the negative charge image is developed with a magnetic brush device 13. This magnetic brush device 13 consists of a magnet, on the surface of which a magnetic carrier mixed with image powder (toner) is held. The magnetic field holds the carrier particles in a brush-like shape. When this brush runs over the image areas, image powder particles are drawn from the brush onto the sheet of carrier material. Such magnetic brush development is described in detail in US Pat. Nos. 2,930,351 and 3,058,444.
The development methods described above and shown in Figures 4 and 5 are only examples, and there are many methods which can be used to develop the induced electrostatic latent image. Any conventional electrostatic development method can be used. The only limitation is that development must take place within a short time after the sheet of support material has been peeled off the photoconductive layer. The following examples

709 642/10

show typical applications of the method according to the invention.

Example I.

An image plate made of an aluminum backing with a 50 micrometer thick layer of glass-shaped Selenium becomes uniform in the dark with the help of a corona discharge to a potential of about 800 V charged. A light-and-shadow pattern to be read from the right is projected onto the charged plate, the charge disappears in the illuminated areas. A sheet of paper that is on a relative Moisture at about 10% is maintained on the Surface of the plate brought. The top surface of the paper sheet comes into contact with one a conductive rubber roller lying at a potential of +100 V. The sheet of paper is then provided with a Lifted off the plate at a speed of about 25.5 cm per second. While lifting, the touches upper surface at the separation point a conductive magnetic brush device, which is at a potential of held about 100 volts as in the U.S. patent 29 30 351 is described. The latent image is then developed with powder particles. The dust bearing Sheet of paper is heated until the image powder melts and then cooled, making the image permanent is fixed. A very good image is obtained with great blackness and sharpness, in which about 10 pairs of lines " can be seen per millimeter. The above procedure is repeated 25 times with 25 additional sheets of paper. The image quality on these sheets remains very good. A very small, almost imperceptible decrease in Image strength is to be determined. This takes place through the dark decay of the photoconductive layer. This progressive Disappearance of the charge in the photoconductive layer is so gradual that a large numbers of satisfactory copies can be made from a single image.

Example II

The process steps from Example I are repeated, using paper with a relative humidity of about 30% is used. The quality of the pictures produced is very good again, the maximum resolution is possible however, decreased to about 4 lines per mm. Again, a large number of identical copies can be made with little Quality waste are produced.

Example III

The process steps from Example I are repeated, using paper with a relative humidity of about 50%. The pictures still have a good one Strength. However, the sharpness is not quite as great as those made on paper with less moisture Images.

Example IV

The process steps from Example I are repeated. Instead of a paper sheet, however, a Sheet of cellophane that has a thickness of about 50 microns and a relative humidity of about 50% has used The dust pattern is fixed on the cellophane with the help of tritetrachlorethylene vapor. Man receives images of very good quality, and in turn it can produce a majority of almost equally good copies getting produced.

Example V

A photoconductive plate is charged and exposed as in Example I. A sheet of paper is placed on the the photoconductive plate bearing the electrostatic latent image. A metal roll at the potential of the areas now exposed, around + 90V, will be applied to the

[o upper surface of the paper sheet brought. This Roller has a large number of very small notches or grooves on its surface. These notches are how in Fig. 4, filled with ink by means of a wick device. The sheet of paper becomes as it rolls touched, lifted from the photoconductive surface. If the paper sheet is guided along the roller, so ink is applied to the sheet according to the shape of the image. However, you get a good quality picture with some unwanted ink on underground areas. The above process steps are followed by 25 more Sheets of paper repeatedly. The image on the 25th sheet is almost of the same quality as that on the first. Although a reduction in quality due to the dark decay of the charge on the photoconductive surface is observed, it appears that many more satisfactory copies could be made.

> - ~ "Example" VI

The exposure and development steps are as in Example I. However, it is the magnetic brush device brought into contact with the lower surface of the paper sheet (at 10% relative humidity), when it is lifted from the plate. This arrangement is shown in Fig.5. The resulting picture is of very good quality and sharper than that generated in example I, since no field scattering occurs because the field does not penetrate the paper.

Example VII

The steps from Example VI are carried out with a paper with a relative humidity of about 50% repeated. A satisfactory image is obtained although the strength and sharpness are lower than those in Example VI. The decrease in quality is a consequence of the time between the lifting of the sheet and the Development goes by as the paper conducts better with greater moisture, which means faster The latent electrostatic image decays.

Example VIII

A photoconductive plate is charged and exposed as in Example I. A sheet of paper with a relative About 10% moisture is placed on the plate and the top surface of the sheet is grounded. The Sheet is lifted from the platen while it touches a conductive developer-dispenser sheet that is on its surface bears a layer of electroscopic developing powder. This powder is in the transferred to the exposed areas on the paper sheet. An image of very good quality is obtained. The above Process steps are repeated with 25 more sheets of paper. The image quality is low Quality reduction from the first to the 25th copy equally good

1 sheet of drawings

Claims (3)

Patent claims: 1. Process for the production of charge images on insulating sheets, in which an insulating Sheet completely in contact with an image plate carrying a charge image and from this one End to the other is gradually lifted off, in the area of the lift-off line on the free An electrically conductive roller is unrolled on the back of the insulating sheet, characterized in that that for the production of several charge images from a single charge image, the electrically conductive roller (8) at a potential of the polarity and size of the background potential of the primary charge image held or grounded will. 2. The method according to claim 1, characterized in that a sheet with a specific resistance in the range of 10 ⁷ to 10 ¹⁴ , preferably in the range of 10 ⁹ to 10 ¹² ohm ■ cm is used. 3. The method according to claim 1 or 2, characterized in that the sheet at a speed lifted between 5 and 100 cm per second.