DE2141918A1 - Electrophotographic process and recording medium for its implementation - Google Patents

Description

7235-71 Dr.v.B / hs 2 1 A 1 91 8

RCA 61,559

US-PA 68,067

AT: August 31, 1970

Applicant: RCA Corporation, New York, N.Y., V.St.ν.Α.

Electrophotographic process and recording medium

for its implementation

The present invention relates to an electrophotographic process, in which successively a photographic process The layer of a recording medium is electrostatically charged, the charged layer is selectively charged by an image of light discharged, and the thereby generated latent electrostatic charge image by an electroscopic toner with generation a visible image is developed on the layer. The invention also relates to an electrophotographic Recording media for carrying out such a method.

The method and the recording medium according to the invention are particularly suitable where this is on the recording medium developed toner image on an image receiving material, e.g. an ordinary sheet of paper is to be transferred.

209810/1640 ORiGiNAL INSPECTED

It is known that the photoconductive layer of an electrophotographic recording medium is formed by a corona discharge to charge. This type of charging has proven itself and is used on a large scale, disadvantageous what is important, however, is that a relatively expensive high-voltage source is used to supply the device generating the corona discharge is required that is able to deliver at least 5 kV. Furthermore, the corona discharge must be carefully isolated and protected in order to avoid endangering users and maintenance personnel from the high voltage. The shielding must also ensure that radio and television interference does not occur.

The present invention is accordingly based on the object of using a high voltage for electrostatic purposes To make charging an electrophotographic recording medium superfluous.

According to the invention this object is achieved by an electrophotographic Method of the type mentioned above, which is characterized in that a photoconductive layer in Form of one or more elementary bodies from a photoconductive and pyroelectric material is provided which are oriented so that when the temperature of the layer changes on the opposite sides of which electrostatic charges of opposite signs appear, and that the charge the layer is effected by changing its temperature.

An electrophotographic recording medium for carrying out this process, which has a layer of a photoconductive Contains material is, according to the invention, characterized in that the photoconductive material is pyroelectric and is oriented so that when its temperature changes, electrostatic charges are deposited on an exposed surface dar layer occur.

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thus, the present invention becomes the corona discharge device and the associated high-voltage source are superfluous. This also means that the institutions owned by these institutions also fall Disadvantages gone.

The concept of the invention is explained below with the aid of Drawing explained in more detail »show it:

Fig. 1 is a perspective view of the hexagonal structure of photoconductive and pyroelectric Zinc oxide rait the polar C-axis *

2 shows a plan view of part of a plate-shaped electrophotographic recording medium according to one Embodiment of the invention, the elementary body from the Einkristallina shown in Fig. 1 material contains;

3 is a cross-sectional view of part of the plate-shaped electrophotographic recording medium according to FIG Fig. 2, seen in a plane 3-3;

Figure 4 is a side view of a record carrier according to the invention and one only partially and schematically illustrated arrangement for its charging according to an embodiment example of the method according to the invention, and

5 and 6 are side views of a plate-shaped electrophotographic recording medium according to an exemplary embodiment of the invention during various stages of an electrophotographic process for forming images on the recording medium.

Fig. 1 shows schematically a monocrystalline, photoconductive and pyroelectric material in the form of a compound 10, which is suitable for the manufacture of an electrophotographic recording medium according to the invention. The Ver- · Bond 10 can, for example, be a hexagonally crystallizing zinc oxide single crystal. be the opposite polar (0001) -Surfaces 12 and 14 that are related to the direction of the C-axis

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are different: the surface 14 can be used as a Zn surface and the surface 12 is referred to as the O-surface. Hereinafter the concept of the invention is primarily described with reference to zinc oxide as the pyroelectric compound 10 can of course be used to carry out the method according to the invention as well as for the electrophotographic Recording media according to the invention also use other pyroelectric compounds, such as CdS, SbSJ or CdSe and others.

When the temperature of the pyroelectric junction is changed, it arises between the opposing surfaces 12 and 14, which run transversely to the C-axis 16, an electrical voltage. For example, if you change the temperature of the Single crystal from compound 10 by about 5 ° C occurs the surface 12 has a negative electrostatic charge with respect to the surface 14, on which a positive electrostatic Charge arises. The polarities of the electrostatic charges on surfaces 12 and 14 depend on whether the C ™ axis 16 with respect to surfaces 12 and 14 in Fig. 1 in Direction of the part 18 upwards or in the direction of the part downwards. The size of the between surfaces 12 and With a given temperature change, the resulting voltage is proportional to the thickness of the crystal from the connection 10 between surfaces 12 and 14.

One way to determine the polarities of the electrostatic charges appearing on surfaces 12 and 14 of the pyroelectric compound 10 occur, is one of the (1010) faces 22 of the prismatic crystal with 40% ger To etch hydrofluoric acid. Etching pits 24 (of which only one is shown in FIG. 1) arise from those facing the direction the polar C-axis can be closed. The etch pits 24 each have the shape of an arrowhead that goes into the positive The direction of the C-axis. The etch pit 24 in Figure 2 thus indicates that the positive direction of the polar axis 16 is equal to the Direction of arrow 20, while arrow 18 points in the negative direction.

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The pyroelectric compound 10 of zinc oxide can be grown by any known method, it is also available in stores. Zinc oxide crystals are either uncut or available cut in the form of disks 28, the surfaces of which run parallel to the crystal surfaces 12 and 14, Cut crystals are commercially available with diameters from 1mm to 5mm and in different sizes depending on the diameter Lengths between 2mm and 10mm available. There are also square discs made of zinc oxide with a side length of 10mm and a thickness of at least 5mm. The zinc oxide is preferably doped, for example with copper (concentration approx

1 Q? O - ^ 1 fi - ^

10 - 10 cm) or lithium (concentration about 5 * 10 cm), to compensate the zinc oxide with charge carriers of the p-type and to set a desired specific resistance. In the case of doping, the dark resistance of the disks 28 is the

G
Binding at least 10 ohm cm, usually even much higher. Doped zinc oxide single crystals have a light resistance of about 10 ohm cm.

2 and 3 show an embodiment of a recording medium according to the invention, which has the form of an electrophotographic plate, as can be used in an electrophotographic method for reproducing original images. The plate 30 contains an electrically conductive substrate 32, for example a sheet of aluminum, copper or stainless steel, and a photoconductive layer 34 made of one or more disks 28 of a pyroelectric compound. It can be seen from FIGS. 2 and 3 that the photoconductive layer 34 is composed of a number of individual pyroelectric bodies (elementary bodies), such as disks 28. The disks 28 are connected to the substrate 32 by any suitable electrically conductive paste 36 or by solder. The disks 28 shown in FIGS. 2 and 3 are hexagonal, as corresponds to the crystal structure of zinc oxide, but they can also have other shapes and, for example, be square or rectangular. The opposite sides 38 ″ and 40 (large major surfaces) of the layer 34 should, however, be substantially contiguous, ie the discs 28 should be as close as possible

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adjoin each other so that they have smooth, continuous side surfaces 38 and 40 form. The lower sides of the disks 28, which are in electrical contact with the substrate 32, can be coated with a very thin indiura layer to ensure a good electrical connection with the substrate 32 through the conductive Ensure paste 36. The discs 28 for the composite Layer 24 preferably each have a thickness of

2 at least 0.5mm, a side surface of at least 2.5mm and

a specific dark resistance of at least 10 ohm cm.

The electrophotographic platen disks 28 are all oriented with their C-axes on opposite sides 38 and 40 of layer 34 intersect, preferably the C-axes are perpendicular to the sides of layer 34. Since the photoconductive Zinc oxide is negatively charged in most electrophotographic processes, the zinc oxide disks 28 become the compound 10 in the layer 34 preferably arranged so that their C-axes point outwards from the upper side 38 of the layer 34, that is, in the direction of arrow 18 (Fig. 1). If the temperature of the layer 34 is increased, then it arises on the upper one Main surface of the side 38 of the layer 34 has a negative electrostatic 'Charge? as will be explained in more detail below. On the other hand, the top side 38 of the photoconductive layer 34 are positively charged electrostatically if the temperature of the layer 34 suddenly starts from the ambient temperature is lowered.

The top side 33 of the photoconductive layer 34 is preferably coated with a monomolecular or monolayer of one or more sensitizing dyes, such as Fluorescein, a cyanine dye, rose bengal, or erythrosine, to make the photoconductive layer sensitive to visible light. Without this dye sensitization, the photoconductive Layer 34 of the zinc oxide disks 28 can be exposed to ultraviolet light to which they are particularly sensitive is.

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4 shows an electrostatic charging arrangement of the present electrophotographic plate 30 by changing the temperature in the dark according to the present method. The device contains a heating device 42 arranged at the plate 30 in the form of a heating plate. The heating device is fed by a voltage source via a switch 46. To charge the electrophotographic plate 30, the switch 46 is closed and the heater 42 is turned on. The pyroelectric voltage developing on the photoconductive layer of the photographic plate 30 in the dark is proportional to the thickness of the layer 34, i.e. the plates 28, and the temperature change of the layer 34. If the photoconductive layer 34 is about 0.7 mm thick and its temperature is around When the C-axes of the disks 28 are directed outwards from the upper side 38 of the photoconductive layer, the upper side 38 becomes negatively charged and the lower side 40 is charged positive, as shown in FIG. 4, however, if the C-axes of the disks 28 were pointing from the top down, the polarities of the charges on the sides 38 and 40 of the photoconductive layer 34 would be reversed.

A change in the temperature of the photoconductive layer 34 of about 5 ⁰ C to about 30 ⁰ C above the ambient temperature has been found to be suitable to charge the present electrophotographic plate 30 for use in an electrophotographic process. With a temperature change of less than 5 ^° C., the resulting charge may not be sufficient, in particular if the layer 34 is relatively thin, while with a temperature change of more than 30 ° C. there is the risk that the conductivity of the layer becomes so great that the layer no longer holds the charge long enough.

The present electrophotographic plate 30 is heated for charging preferentially over the ambient temperature, but can be the electrophotographic plate 30 also charge characterized ,, that it cools to, for example, about 5 ° C to about 30 ⁰ C above the ambient temperature. This can be done by

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happen that you have cooled air on the surface 38 of the Layer 34 blows, e.g. 3. by means of a number of nozzles 47 which are arranged above the photoconductive layer 34, as FIG. 4 shows. The cooling can also be done in other ways, e.g. by Peltier elen

. The charged electrophotographic plate 30 can now be exposed to a light image to be reproduced When the electrophotographic plate 30 is selectively discharged, an electrostatic latent image is formed on the photoconductive one Layer 34. This method step is shown schematically in FIG. A transparency 48 to be copied

E.g. a single image of a movie 50 is captured by means of a Projector 52 is projected onto the upper side 38 of a photoconductive layer 34 which has been previously charged by heating. The exposure should take place as soon as possible after the layer has been charged, in order to minimize the loss of charge due to temperature changes possible to keep. The areas of the photoconductive ones hit by the light Layer 34 is discharged according to the illuminance and an electrostatic charge image is created. The exposure time depends on the dimensions of the electrophotographic plate 30 and the illuminance, it can e.g. on the order of a second.

The electrostatic latent image on the electrophotographic plate 30 can now be made in any known manner to be developed. For example, a magnetic brush can be passed over side 38 of the electrophotographic layer, which contains a magnet 54 from which a triboelectric mixture 56 of iron and toner particles hangs. The toner particles 58 are positively charged in the triboelectric mixture 56 and are made up of the negative charges of the latent electrostatic Is attracted to the image developed thereby, as shown in FIG. The developed charge image can now, e.g. by heating, fixed on the upper side 38 of the photoconductive layer 34 or the unfixed image can be used in a manner known per se Manner onto an image receiving material such as a sheet of paper and fix there.

209810/1640 ^ßAü

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It had already been mentioned that one for the present electrophotographic recording medium instead of the described photoconductive and pyroelectric single crystal disks made of zinc oxide can also use other pyroelectric photoconductive compounds. Connections that do not know such as CdS, SbSJ or CdSe can of course despite their body color, which is unfavorable for permanent recording media can easily be used for electrophotographic plates from which the toner images are transferred to another image receiving material is transmitted.

The above-mentioned materials, dimensions, for example and process conditions can of course be set in the ™ modify various tit without going beyond the scope of the invention.

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Claims (11)

Claims ίΐ / Adhesive photographic process in which.! one after the other a photoconductive layer of a recording medium is electrostatically charged / the charged layer is selectively discharged by a light image and the latent electrostatic charge image produced is developed by an electroscopic Toner ™ to produce a visible image on the layer, characterized in that a photoconductive layer in the form one or more elementary bodies (28) made of a photoconductive and pyroelectric material are provided which are oriented such that when the temperature of the layer changes, electrostatic charges of opposite signs appear on the opposite sides thereof; and that the layer is charged by changing its temperature. 2. The method according to claim 1, characterized characterized in that the temperature of the layer is around 5 ° C to 30 ° C is increased. 3. The method according to claim 1, as through characterized in that the temperature of the layer is around 5 ° C to 30 ° C is lowered. 4. The method according to claim 1, 2 or 3, characterized characterized in that a photoconductive layer is used, the one or more discs (28) of monocrystalline Contains photoconductive zinc oxide on an electrically conductive substrate (32), the C-axes of the zinc oxide single crystals point in the same direction and at least approximately perpendicular to the opposite large side surfaces of the layer, and that the temperature of the layer 209810/1640 is changed by at least 5 C. 5. The method according to claim 4 _f thereby characterized in that the sink oxide single crystals so are arranged so that their C-axes point outward from the side (38) of the layer that is electrically connected to the substrate (32) connected side (40) is opposite. 6. Electrophotographic recording medium for performing the method according to claim 1 with a layer of a photoconductive material, characterized in that that the photoconductive material (10) is pyroelectric and oriented so that when it changes Temperature electrostatic charges on an exposed Surface (38) of the layer (34) occur. 7. Record carrier according to claim 6, characterized in that the layer is composite Contains individual bodies (28) made of the pyroelectric material (10), all of which are oriented at least approximately in the same way. 8. Record carrier according to claim 6 or 7, as characterized in that the individual body or bodies of the layer consist of monocrystalline ZnO, CdS, CdSe λ or SbSJ. 9. Recording medium according to claim 8, characterized in that each individual body (28) has one C-axis (18) and that the C-axes. all individual bodies point in the same direction and are essentially perpendicular the surface (38) of the layer (34). 209810/1640 ₁₂ _ 2 U 1 91 8 10. Record carrier according to claim 6, characterized in that the material is monocrystalline ZnO, that the layer consists of a plurality Contains zinc oxide single crystal disks and that the C-axes of all disks from the exposed surface (38) of the layer (34) pointing outwards. 11. Record carrier according to claim 10, characterized in that the disks each a thickness of at least 0.5 mm, a large side area of at least 2.5mm and a specific dark G
have a resistance of at least 10 ohm cm. 209810/1640