DE2363738C3 - Electrophotographic recording material - Google Patents

Description

The invention relates to an electrophotographic recording material made from a flexible, electrically conductive material conductive layer support, a metallic layer, optionally an intermediate layer and a selenium containing photoconductive layer.

Electrophotographic methods and apparatus for doing this have had a wide range in the art of reproduction Spread found. They are based on the property of the photoconductive material when exposed to a activating radiation to change the electrical resistance.

After being electrically charged and exposed to an activating radiation, a photoconductive radiation can be applied Layer generate a latent electrical charge image that corresponds to the optical image. To the exposed areas there is such an increase in the conductivity of the photoconductive layer that the electrical charge on the conductive carrier at least partially, but in any case more strongly than on the unexposed areas - can flow away, while the electrical charge in the unexposed areas essential is preserved; it can be made visible with an image powder, a so-called toner and the resulting toner image, if necessary, finally on paper or another support be transmitted.

Both organic and inorganic substances are used as electrophotographically active substances used. Among them, selenium, selenium compounds or alloys with selenium are of particular importance attained. Metals, such as preferably aluminum, aluminum alloys, are used as conductive supports Steel and brass. Non-conductive supports with an electrically conductive one are also used as a carrier Coating, for example glass coated with tin dioxide, is used.

Electrophotographic equipment in which the photoconductive layer is applied to a flat plate, are not very suitable for fast continuous operation. The carrier plates are therefore multiple replaced by cylindrical drums. However, these have the disadvantage that due to the curved Surface only transfer the image in strips

ίο can be and the width of this strip by the Depth of field of the imaging system is determined.

lis is therefore necessary that the original or parts of the. Optical system are moved synchronously with the rotation of the drum. At high copying speeds

Γ5th make such precision movements as well considerable difficulties such as the transmission of the required amount of light, because yes within a very A sufficient amount of light must reach the electrophotographic layer for a short time.

It is possible to increase the working speed, if the photoconductive layer does not have a curved, but a flat surface, because then wider strips of the original or the entire original can be displayed at the same time. this

is in known embodiments of electrophotographic devices for example by a flexible Layer carrier reached, which, for example, unwound from a roll and wound onto a second roll or as an endless belt over two or more rollers. The section of tape that is straight is exposed, is stretched to a flat surface. For this purpose are due as a carrier Due to their mechanical properties, tapes made of aluminum steel or brass are suitable, but are also made with

3: i conductive coatings made of aluminum or potassium iodide coated plastic tapes, e.g. made of polyethylene terephthalate polyester film, or tapes made of paper or rubber that are made conductive accordingly woven or nonwoven fibrous tapes made of glass, cotton or silk are used.

The mentioned advantages of such flexible carrier tapes opposes a certain disadvantage in that it is difficult to obtain sufficient adhesive strength between the supports and the photoconductive

4 ;: Maintain layer and avoid damaging the layer while moving. The lasting Bending of the photoconductive layer when redirecting around the rollers results especially at a high Operating speed for the generally relatively hard and brittle glassy photoconductors, even if these only have a very small layer thickness, to the formation of cracks and fractures, so that it eventually the photoconductive layer flakes off the flexible substrates.

It was believed that it was possible to counter these disadvantages of the flexible layer support by the fact that Attempts were made to improve the adhesive strength between the carrier and the photoconductor. To that end is for example, it has been proposed to coat the aluminum prior to applying the photoconductor dun: h to roughen ion bombardment or between the flexible carrier tape and the photoconductive layer one: to apply an intermediate layer that has a good adhesive strength both to the layer support as

(> - ■ also compared to the photoconductor and which, on the other hand, has little adverse effect on the electrophotographic sensitivity of the system as far as possible

mainly made of polymeric organic or organosilicon plastics, e.g. non-conductive Hani binders with or without inclusions of Phthalocyanine pigments or from substituted SiIyI-isobutylethylenediamine. Graphite has also become known as an intermediate layer. The disadvantage of such intermediate layers is, on the one hand, that there is a noticeable Limitation of the electrophotographic sensitivity can hardly be avoided. On the other hand, the Plastic intermediate layers sometimes have layer thicknesses of only 0.1 μm, come the technological ones Difficulty in production is added, especially if at the same time a uniform layer thickness is required. Ultimately, however, the use of such intermediate layers leads, even if initially too Better adhesion should be achieved over time and as a result of fatigue constant bending to the formation of microcracks which the Severely impair or even exclude the usefulness of the electrophotographic recording material.

The object of the invention is, in an electrophotographic recording material made of selenium, selenium compounds or alloys containing selenium deposited on a conductive flexible support via an intermediate layer is applied to improve not only the adhesion between the carrier and photoconductor material, but also the To increase flexural strength to the extent that during the bending of the carrier tape when guided over rollers in microcracks in the photoconductive layer no longer occur and the recording material is functional preserved.

In the case of an electrophotographic recording material comprising a flexible, electrically conductive layer support, a metallic layer, optionally an intermediate layer and a selenium-containing photoconductive layer, according to the invention, the metallic layer is made of a metal with a modulus of elasticity below 6000 kp / mm ² and a recrystallization temperature below 40 ⁰ C exists.

In a preferred embodiment of the invention, the intermediate layer consists of a metal with a modulus of elasticity below 2000 kp / mm ² and a recrystallization temperature below 40 ^° C. In a further embodiment of the invention, the intermediate layer consists of lead with a layer thickness of about 3 to 12 μm, preferably 6 μm, or of indium with a layer thickness of 0.5 to 4 μm, preferably 2 μm, to which the photoconductive layer is then applied in a layer thickness of about 20 to 80 μm. A steel strip with a layer thickness of about 0.05 to 0.2 mm, preferably with a layer thickness of about 0.1 mm, has proven to be a flexible support.

By the invention it is achieved that even when bent to an angle of 18O ⁰ C and a radius down to 25 microcracks mm more in the photoconductive layer and no Abtrennerscheinungen from the substrate occur, because the elastic-plastic well deformable intermediate layer behaves in a stress-relieving manner in certain layer thickness ranges. It is therefore possible to let the flexible belt run over rollers with a relatively small radius, which desirably reduces the space requirement of the devices provided with such belts.

Another advantage is that the layer thickness of the photoconductor is not solely based on criteria its mechanical properties need to be measured, that is, not kept particularly small needs to be, which can be detrimental to the properties of the Could affect recording material and limit its scope. Rather, there are Use of an intermediate layer according to the invention allows the layer thickness of the photoconductor to be selected essentially according to the demands placed on it for the electrophotographic properties. Therefore, photoconductors with layer thicknesses of up to 80 μm can also be used without the risk of damage contact vet. Due to the particularly low recrystallization temperature of the interlayer material retains this even after the bends because of its extended in the plastic area, its plus-elastic behavior without hardening or becoming brittle, and causes the stress relief of the photoconductive layer for the duration.

Contrary to the opinion represented in the professional world that simply by improving the Adhesion with, if necessary, an additional simultaneous reduction in the layer thickness of the photoconductive Layer that can prevent cracking and peeling of the photoconductive layer has rather shown that only and decisively through the measures described below according to the Invention sufficiently increases the flexural strength, thereby preventing the formation of microcracks will.

It can be assumed that due to the interaction of the special properties of the Interlayer both in terms of its modulus of elasticity and its ability to recrystallize within a very specific layer thickness range that occurs when the photoconductive layer is bent occurring tensions are reduced. By reducing the tension, the The risk of the formation of microcracks has been averted, while with the previously usual, solely due to an increase in Adhesion-directed measures just occur unwanted voltage peaks. Surprisingly When using the invention, it is therefore also possible to use photoconductors on the flexible supports Use layer thicknesses of up to 80 μm, while at the conventional intermediate layers, the layer thickness of the photoconductive layer is only 20 'to 35 μm could. Another advantage of the invention can be found in the expansion of the applicable layer thickness range be seen.

It may be useful to place between the metallic intermediate layer and the photoconductive layer Provide a further intermediate layer, which allows the injection of charge carriers from the metallic layer in the photoconductive layer. For this purpose, an aluminum oxide layer is used, for example Layer thickness about 0.1 μm, possibly also less, has, or a thin insulating plastic intermediate layer.

An intermediate layer according to the invention is produced in a manner known per se, for example by galvanic or vapor deposition.

In a special embodiment, which provides lead as the material for the intermediate layer, which with With the help of a vapor deposition process is applied to the flexible carrier, the production of a electrophotographic recording material according to the invention described again in more detail

will.

In this case, one expediently starts from lead, which has a degree of purity of about 99.999% and is evaporated from a chromium-nickel evaporation boat at an evaporation temperature of about 600 to 800 ^° C. and under a pressure of about 5 · 10- · »Torr. The vaporous lead is then deposited on a steel strip of 20 mm width and has a thickness of 0.1 mm at a SubstraUemperatur of 40 to 60 ⁰ C. A photoconductive selenium layer is then deposited with a layer thickness of about 55 microns at a substrate temperature of about 60 ⁰ C and under a pressure of about 5 x 10- ⁶ Torr.

In this way, the sequence of layers shown in the figure in a partially schematic representation is obtained from a carrier 1 on which a photoconductive layer 3 is located via an intermediate layer 2. As tests have shown, occur with a recording material that in the above It is manufactured in a manner that has no microcracks and no chipping when it is at a bending radius of only 11.0 mm is statically bent by a bending angle of 180 °.

1 sheet of drawings

Claims (6)

Patent claims: 1. Electrophotographic recording material consisting of a flexible, electrically conductive layer support, a metallic layer, optionally an intermediate layer and a selenium-containing photoconductive layer, characterized in that the metallic layer consists of a metal with a modulus of elasticity below 6000 kp / mm ² and a recrystallization temperature below 40 ° C. 2. Recording material according to claim I _1, characterized in that the metallic layer consists of lead or indium. 3. Recording material according to claim 1 or 2, characterized in that the metallic layer 3 - 12, preferably 6μπΐ thick and made of lead consists. 4. Recording material according to claim 1 or 2, characterized in that the metallic layer 0.5-4, preferably 2 μm thick and made of indium consists. 5. Recording material according to claim 1 to 4, characterized in that the layer support consists of a 0.05-0.2, preferably 0.1 μm thick steel strip. 6. Recording material according to claim 1 to 5, characterized in that the photoconductive Layer is 20-80 μm thick.