DE1802912A1 - Production of electrostatic images on - highly resistant substrates - Google Patents

Abstract

Material comprises in electric contact (a) transparent contact layer, (b) photoconductor layer, (c) intermediate electrode, (d) pore membrane, (e) high resistance carrier layer and (f) contact layer. either (a) or (c) are connected to a potential source (f) and (c) are earthed. Pore membrane pref. consists of a plastic foil with parallel channels of 50-100 mu m diam. and a resistance 1015 ohm. Channels are filled with metal or resistance material. High resistance material may be paper, if image is to be immediately developed and fixed, or plastic material for image transfer.

Description

Description of the application for a patent on device for Application of charge images to high-resistance carriers is the subject of the invention a device for the direct application of charge images to high-resistance carriers by imagewise exposure of a photoconductive layer.

The ones commonly used in electrophotographic reproduction technology The method is mostly the latent charge image generated on the photoconductive layer either developed directly on the final substrate, such as paper and fixed or the image developed on an intermediate carrier is imprinted on Transfer paper.

These methods have the disadvantage that either an expensive layer-bearing Copy material used or the carrier carrying the photo layer after each use must be freed of image residues, which causes rapid wear of the layer and requires additional measures.

It has also been suggested, on damp, with an electric sensitive layer of prepared paper by color reaction directly a visible one Generate image, this with the interposition of a film that is inserted through Metal wires are only conductive in one direction, in conductive connection with one brought the photoconductive layer carrying the latent charge image and applied a voltage however, this method is of practical use in this form not suitable because it requires exposure times that are too long and also sufficient good contacting of the layers is difficult to achieve. There is also the strength The metal wire cannot be chosen to be arbitrarily small, affects the image resolution limited.

The aim of the invention is to provide a device with which directly on a high-resistance carrier, for example a suitable paper a charge image is generated that is developed or, if desired, in a manner known per se is transferred to another surface. The device is intended for both production of positive as well as negative images.

The invention relates to a device in order to achieve the object set for applying charge images to high-resistance carriers by imagewise exposure a photoconductive layer and is characterized in that the image facing the following layers are arranged in electrically conductive contact with one another are a) transparent contact layer b) photoconductor layer c) intermediate electrode d) pore membrane e) high-resistance carrier layer f) contact layer with either contact layer a) or intermediate electrode c) at a voltage source, contact layer f) and c, or a are on earth.

The transparent contact layer can, for example, consist of a the photoconductor layer evaporated thin metal layer or suitable Metal oxide layer such as indium oxide and must be such that they both there is a sufficiently good contact distributed over the entire surface and sufficient is transparent to the projected image. Lately there are also vapor-deposited layers Can be produced from a mixture of gold and quartz, with good electrical conductivity Have the best possible transparency.

The photoconductor layer can contain photoconductors known per se, where preference should be given to using those whose light / dark resistance values are as possible are far apart. Zinc oxide should be mentioned here in particular, but are at corresponding adaptation of the remaining layers also other photoconductors such as Selenium, antimony trisulfide or also known organic compounds can be used.

The pore membrane according to the invention is characterized in that they are made of a high-resistance plastic film with parallel perforated channels of around 20 to 200, preferably 50 to 100 µm diameter and a spec. Resistance of> 1015A cm. Such membranes are made of any plastic material in a simple manner Can be produced by electron beam perforation, with large hole densities with great accuracy can be achieved. The thickness of the foil should be around 50 to some 100 / µm.

The specified resistance range must not be significantly lower are undercut, common plastics such as polyester, polystyrene, Polytetrachlorethylene and others are above this range.

According to the invention, the channels of the pore membrane are either electrically connected conductive material or a resistance material, the properties of which are below are described in more detail, filled. In particular, conductive silver is used as the electrical conductor or colloidal graphite in question, especially a brushable resistance material Paste that is easy to apply into the holes. When making the stuffed Pore membrane care must be taken that there are no conductive webs on the surface are.

The intermediate electrode, which is used for contacting in the case of manufacture used for positive images, can consist of a metal wire mesh, for example, in the case of using metal-filled pore membranes, it is wrapped in a resistive layer embedded or can be vapor-deposited directly onto the pore membrane. Using The intermediate electrode is made of pore membranes filled with resistance material preferably through Applied by vapor deposition of a metal layer. Here For example, the pore membrane can be coated with aluminum before the holes are made be steamed. Before filling the pores with resistor material, the metal layer should in the area of the individual pores is etched to a diameter larger than the pore diameter will. This results in a better division of the current paths for the light or Dark state reached. The intermediate electrode can, however, as with the metal-filled Pore membranes also consist of a metal mesh. In this case the resistor material of the individual pores embed the entire intermediate electrode. The disorder of the intermediate electrode is explained in more detail below with reference to the drawings.

The type of high-resistance carrier layer can depend on the desired The way in which the image is to be visualized can be selected. she can consist of a suitable high-resistance paper on which the image develops immediately and is fixed, or in the case of an image transfer from a plastic film or like that.

The lower contact layer must as well as the upper transparent layer guarantee a perfect contact over the total area and can for example the end consist of a metallized rubber layer.

The device according to the invention is also provided with a voltage source, preferably an AC voltage source, which allows a pulse of about 800 volts and 10 / usec. Depending on whether negative or positive Images are to be produced, the contact is made either on the transparent Contact layer a, the intermediate electrode and contact layer f being connected to earth or at the intermediate electrode c, in which case contact layers a and f are then connected to earth.

The invention is explained in more detail by means of the drawings, namely, Fig. 1 shows the device according to the invention in the case of use of metal-filled pore membranes, FIGS. 2 and 3 show a detailed view of the intermediate electrode 4 shows the device when using pore membranes filled with resistance material Fig. 5 is a view of the pores seen from below.

The individual layers are shown in the illustrations with denotes the letters a-f, in the embodiment according to FIG. 1, an intermediate electrode used, which is embedded in a resistor material 1 in the form of a metal grid is. The contact is shown switchable from position I to position II.

In one embodiment, the copying material was an electrostatic Recording paper with a high-resistance coating for negative, imagewise charging (Use of a positively charged toner powder) is provided. Should the copying process can be achieved by positive charging, the external power source must be connected to ground have positive potential. When copying, the recording paper becomes so between the electrical contact plate f and the one for the pixel-wise charge transfer required pore membrane d placed that over the entire surface a good contact consists. This can be achieved relatively easily when used as a contact plate an electrically conductive rubber sheet is used. As the pore membrane d In the example shown, a 100 Ju thick Hostaphan film is used. The foil had parallel perforated channels about 50 1u in diameter. The holes were the same Distances of about 200 / u from each other. The holes were made using an electron beam drill manufactured. In principle, any other pore membrane can also be used can be used if they are made of a sufficiently high-resistance material. The holes in the insulating film were filled with conductive silver. It is advantageous, the lower end faces of these contact columns with additional metal domes to prove what can be done galvanically, for example, and then grind all metal tips to the same height. This makes one special uniform contact achieved. The top of the pore membrane is covered with a mesh-like intermediate electrode c occupied in such a way that the individual contact pillars are in each case in the free spaces between this bubble grid and so no electrical contact between the individual contact pillars and the intermediate electrode consists. In the present case, the intermediate electrode consists of a metal wire mesh from approx.

50 / u wire diameter. Another way to apply the The intermediate electrode is the vapor deposition of a metal grid through a mask. The whole Space between the contact tracks of the intermediate electrode is made with an electrical Resistance material 1 filled out. The resistivity is the resistance material must be adapted to the photoconductor layer used. He should be in the middle range between light and dark resistance the photoconductor layer. In the present case, the photoconductor layer b was applied to the resistive layer, whose thickness should be at least 50 Xu. As a photoconductive material in experiments Zinc oxide used. By adding appropriate sensitizers, a desired spectral range can be set. For connection to the external circuit the photoconductor layer is coated with an electrically conductive contact layer a, which has only a very weak absorbing effect in the spectral range used.

This contact layer can, for example, optically by vapor deposition permeable gold or aluminum layer can be produced.

Was in a device as shown in Fig. 1, on the contact layer a creates the image of a template, then a voltage pulse of approx. -400 volts approx.

10, usec (position 1) abandoned and that on the electrostatic The latent image obtained from recording paper has a latent image which is common in electrophotography Powder developer developed and fixed, so a sharp image of the original was created obtain.

Fig. 4 shows an embodiment of the invention in which the pore membrane filled in with a resistor material is. For this material the same conditions apply as mentioned above for embedding layer 1, it is also necessary here that the material be easily introduced into the pores is.

As such, when using ZnO as a photoconductor, for example Cellulose acetate in question, which is applied from solution or dipped into the pores can be.

The specific resistance can vary depending on the choice of plasticizer to the most favorable range between light and dark resistance of the photoconductor from 1011 to 1013 cm cm. The intermediate electrode c is in this Case as described on page 6, first paragraph, applied. By the way, is the Device constructed in accordance with that shown in FIG. 1, and also with regard to The same considerations apply to the contacting.

The device according to FIG. 1 is more advantageous for many applications, because the pore resistances are very low, 80 that any pore membrane thickness can be chosen. In addition, by arranging the in the resistor material embedded intermediate electrode with relatively large distances between the Metal grid of the intermediate electrode and the individual pore fillings a good division of the current paths in the resistor material.

According to the invention can be in a simple manner on any high-resistance carrier material positive or negative images produced in good quality will.

The device is particularly simple in construction and easy to handle. In adaptation to the requirements of the practice required in each case, the invention of course in many ways, for example with regard to the other Processing of the latent charge images.

Claims (7)

Claims 1. Device for applying charge images to high-resistance carriers by imagewise exposure of a photoconductive layer, characterized in that that facing the figure, the following layers are in electrically conductive contact are arranged with one another a) transparent contact layer b) photoconductor layer c) intermediate electrode d) pore membrane e) high-resistance carrier layer f) contact layer where either contact layer a or intermediate electrode c at a voltage source, Contact layer f and c or a are connected to earth. 2. Device according to claim 1, characterized in that the pore membrane made of a high-resistance plastic film with parallel perforated channels from about 20 to 200, preferably 50 to 100 µm in diameter and a resistance of> 1015au cm. 3. Apparatus according to claim 2, characterized in that the perforated channels are filled with metal or a resistor material. 4. Apparatus according to claim 1, characterized in that the intermediate electrode consists of a metallic net. 5. Apparatus according to claim 3, characterized in that in the event metal-filled perforated channels, the intermediate electrode in a resistor material is embedded. 6. Apparatus according to claim 1, characterized in that a photoconductor with a large light-dark resistance range is used. 7. Apparatus according to claim 3 and 5, characterized in that the resistance of the material within a range of a power of ten above or below the light, baw. Dark resistance range of the photoconductor. Blank page