DE1137449B - Image recording method - Google Patents

Description

It is known that with a change in temperature of substances also a change in their specific electrical resistance is connected. Also high molecular weight resins of very different composition lower their electrical power when they are heated from room temperature to around 100 ° C Resistance by several powers of ten.

It was surprising that these high molecular weight resins show their state of decreased resistance still maintained for a certain time after the end of the exposure to heat, if its Temperature is lowered below the exposure temperature or back to the initial value has decreased. The present invention is based on this property.

The present invention relates to an image recording method by imagewise exposure of heat on a resin layer, which increases its specific electrical resistance when applied of heat, which is characterized in that heat is applied imagewise to the resin layer can act, the resin layer is then electrostatically charged and the latent electrostatic image makes visible by means of known methods of electrophotography and, if necessary, fixed.

The imagewise application of heat to the resin layer can be carried out in various ways be e.g. B. you irradiate them optically with heat rays, or you bring them with you in contact with an imagewise shaped warm object, or under-irradiate the resin layer an original with heat rays, the heat being absorbed mainly at the image areas of the original and passed on to the resin layer. The action of the heat can therefore both on the contact path as well as by absorption of rays in the resin layer.

Heated bodies of the usual type, for example those on the market, can be used as heat sources Radiant heaters, whose temperature is used in such a case, in which one radiates heat image-wise generation used, about 400 to about 2500 ° C, preferably 1500 to 2000 ° C, is. It bodies that are at a sufficient temperature can also be used as stamps.

The specific electrical resistance decreases at the heated areas. the The layer can be heated to the melting point or above, but one is usually sufficient significantly less heating in order to achieve a sufficient effect. In many cases it is sufficient a heating by 150 ° C, preferably by about image recording processes

Applicant:

Kalle Aktiengesellschaft,
Wiesbaden-Biebrich, Rheingaustr. 190-196

Dr. Erwin Lind, Wiesbaden-Biebrich,
has been named as the inventor

100 ° C or below for adequate differentiation to ensure.

After the imagewise exposure to heat has ended, the resin layer is brought to a temperature which is lower than the temperature at which the image-wise exposure takes place. This can be done in different ways Wise done, for example, by removing the heat source, whereby the resin layer cools down by itself to a lower temperature. Also a quick quenching by introducing The layer in a cooling device brings good results. Advantageously, the layer is again brought to the starting temperature it had before the exposure to heat, but can also higher and lower temperatures are used. In this way, one will be on the resin layer creates a latent electrical resistance image, in which the image areas are opposite to the non-image areas have lower electrical resistance.

Resins to be used according to the invention are those whose specific resistance under normal conditions is in the range from about 10 ¹² Ω · cm to about 10 ¹⁹ Ω · cm and whose specific resistance at the contact surfaces with ultra-red absorbing image areas of the original when exposed to heat is at least about two powers of ten lower. This specific resistance of the resin layer, which has decreased during the heat irradiation, is preferably below 10 ¹⁰ to 10 ¹² Ω · cm.

The suitability of a resin layer for the method according to the invention is determined, for example, by that the electrical volume resistance of the layer as a function of the temperature determined, which shows whether there is a sufficient decrease in resistance when the temperature increases

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entry. The drop in resistance of the resin layer applied to the base with increasing temperature can with some resins by adding plasticizers to the resin in question Polystyrene, for example, tricresyl phosphate is suitable - to be improved, so that a very sets favorable resistance behavior.

The usefulness of the resins for the invention Method can also be determined in a simple manner by the fact that the solution of a such resin on a carrier material, e.g. B. poured onto a sheet of paper, the solvent in one moderately warm air flow removed, then a template is placed on the layer, with a thermal radiation for briefly irradiated through the template and then the layer is charged by a corona discharge and bringing the layer thus charged into contact with an electroscopic powder. If at the applied temperature a sufficient resistance differentiation has occurred, one obtains an image of the original.

Resins to be used in the present invention under the above-mentioned conditions can be used both synthetic and natural resins in question, for example polyolefins such as polyethylene, polyisobutylene, Polypropylene, polybutylene, polyvinyl compounds such as polyvinyl chloride, post-chlorinated polyvinyl chloride, Polyvinyl acetate, polystyrene, especially modified polystyrene, copolymers and polymer mixtures from the aforementioned compounds, polyesters, such as polyterephthalic acid esters, cellulose esters, such as cellulose acetate, cellulose propionate, maleinate resins, coumarone resins and ketone resins.

Among the natural resins, shellac, for example, has advantages that its use according to make the present invention advantageous. Also conversion products of natural resins, such as polymerized resins are well suited.

The resins on which the resist images are created can be in self-supporting form as such be used or applied to a base; z. B. in a known manner in the form of a Melt or from solvents or in the form of dispersions. The thickness of the applied resin layer can vary within wide limits. You can z. B. apply layers between 10 and 30 μ. Thinner or thicker layers can also be used. If you look at the images of resistance - in the manner to be described below - wants to make visible, it is often useful to Layers not below 5 μ should not be selected to avoid strikethrough when applying electrostatic charge to prevent. Very different substances are used as carrier material, for example those made of paper, Plastics, metals, ceramics, glass, in question. Films made from these are particularly useful Fabrics used.

The above-mentioned latent electrical resistance images can be converted into a visible image will. To do this, the resistor images are charged with a corona discharge. Do not stay with them The areas mentioned receive a charge, while the heated areas have a much lower charge Have resistance, the charge at least partially flows off again, so that one can see the resistance image corresponding electrostatic image is obtained, which in a known manner by contacting with a finely divided colored resin or soot particles are converted into a visible image which, when heated, is converted into a visible image or can be fixed by the action of solvent vapors. For the one just mentioned In this case, the resins are advantageously applied to a carrier that has sufficient electrical conductivity have, for example foils or plates made of metal, superficially conductive for electrical charges made glass plates, paper, plates or foils of electrically conductive fiber-free material

ίο (plastics, resins). ^{Substances with a specific resistance of at most 10 11} Ω · cm are considered to be sufficiently electrically conductive for the purposes of the present invention. If you use paper as a base for the layer that becomes conductive in the heat, it is advisable to pretreat the paper to prevent the penetration of the coating solution, e.g. B. with methyl cellulose in aqueous solution or polyvinyl alcohol in aqueous solution or with a solution of a copolymer of methyl acrylate and acrylonitrile in acetone and methyl ethyl ketone or with solutions of polyamides in aqueous alcohols. Aqueous dispersions of such substances suitable for pretreating the paper surface can also be used.

If cellulose acetate is used as the resin on a waterproof carrier material, then according to the Image production described above and fixation of the image areas by the action of heat by means of superficial saponification of the cellulose acetate in the non-image areas, for example by alcoholic Potash lye to make these places suitable for the water supply and thus printing forms for the Manufacture flat printing.

In the case of transparent carrier material, intermediate originals can be placed on any light-sensitive material to be paused Material received.

If you want to use the resistance images for registration purposes, you have to make sure that the resin layer absorbs enough heat rays.

This can be done by adding a material that absorbs ultrared rays, such as carbon black, to the layer. incorporated or that an appropriate absorbent layer is applied in contact with the layer. You can use the resin layer z. B. on ultra-red absorbing carrier material, such as black colored Paper. The resistance images obtained after exposure to heat can then by electrostatic charging and developing with a white or differently colored resin powder be made visible. You can also use colorless material if you use it during the irradiation brings into close contact with an ultra-red absorbing body with ultra-red rays. In addition for example, the recording material is left over a blackened roller during the action of heat walk or bring it into close contact with a blackened film, for example, during this time a blackened silver film.

example 1

A base paper with a basis weight of 80 g / m ² is coated with polyethylene by extrusion so that the layer thickness is about 15 μ. A template labeled on one side is placed on top of the polyethylene layer. The copying material arranged in this way is guided past a focused 1350 watt ultrared radiator in close contact at a speed of a few meters per minute. Through the

Ultrared absorption in the template creates a thermal image that is due to the close contact with the Polyethylene layer is transferred. The specific electrical resistance of the polyethylene layer drops at the image points, and a resistance differentiation is obtained, which corresponds to the image areas of the original. Around this latent "image of resistance" visible To make, the polyethylene layer is raised to a surface potential of with a corona device Electrostatically charged about 300 volts positive to earth. The latent "image of resistance" is transformed This results in a latent charge image, which is a negative to the original, as it is transferred through the transfer of the thermal image, places of lower resistance generated by the applied charges immediately flow away. Only on the unheated areas corresponding to the non-image areas of the original the applied electrostatic charge remains. The electrostatic one, negative compared to the original Charge image is made visible by a developer, the ζ. B. from 100 parts by weight of glass spheres with a grain size of 300 to 400 μ and 25 parts by weight of a resin powder with a grain size of 20 to 50 μ consists.

The resin powder Peerless carbon obtained by melting together 30 parts by weight of polystyrene, 30 parts by weight of resin-modified maleic acid resin (Beckacite ^(R> K105 a registered trademark of Reichhold Chemie AG Hamburg) and 3 parts by weight of carbon black (Peerles ^<R> Black Russ 552 a registered trademark of the company. Black Co), subsequent marriage and sifting.

Example 2

With a solution of 10 parts by weight of polyvinyl chloride in 75 parts by volume of ethyl acetate, a wax base paper with a basis weight of 40 g / m ^{2 is} coated on two sides by machine. After the layers have dried, the copy material is placed on an original with one or two sides written on it and exposed to radiation with ultrared from the side facing away from the original. A differentiation in resistance behavior is obtained on the surface of the polyvinyl chloride layer which corresponds to the image areas of the original and which is sufficiently preserved for up to an hour, so that after this time there is still a conversion into an electrostatic charge image, as detailed in Example 1 is described is possible. The charge image is made visible in a known manner by dusting with a colored resin powder.

Example 3

A 30μ thick cellulose acetate film is laminated onto a paper made waterproof with melamine resin and having a weight per unit area of 140 g / m ^2. The cellulose acetate layer is exposed to a brief, intensive irradiation with ultrared under a film template. The latent image formed on the acetate layer is made visible by the acetate layer being electrostatically positively charged with the aid of a corona and the resulting charge image made visible with the developer of glass beads and resin powder described in more detail in Example 1. After fixing the powder image by briefly heating it, it is possible to transfer the copy obtained into a planographic printing form. To do this, the image-bearing acetate layer is wiped over with a methanolic solution of potassium hydroxide solution, which is obtained by dissolving 12 parts by weight of potassium hydroxide in 90 parts by volume of methanol and making up to 150 volumes by volume with water. The acetate film is saponified in the non-image areas by the methanolic potassium hydroxide solution, while the image areas consisting of the fixed resin powder are retained. The image-free areas are water-bearing in contrast to the image areas, which can be colored with bold paint. The paper printing film obtained can be used for printing in a planographic printing apparatus.

Example 4

A solution of 22 parts by weight of a maleate resin with a softening point of 95 ° to 105 ° C. in 200 parts by volume of ethyl alcohol is applied by machine to ^{paper with a surface weight of 110 g / m 2 which has been prepainted to prevent the penetration of organic solvents.} After the layer has dried, the copy material is briefly exposed to ultra-red irradiation under a positive film master. In order to make the latent image visible, the maleate resin layer is electrostatically positively charged with the aid of a corona discharge. The electrostatic charge only adheres to the areas of the copy layer that are not heated from the original. The result is a negative charge image compared to the original. This is made visible by treatment with the developer of glass beads and a colored resin powder described in Example 1. The powder image is fixed by briefly treating it with trichlorethylene vapors.

Claims (1)

PATENT CLAIM: Image recording process by imagewise exposure of heat to a resin layer which reduces its electrical resistivity when exposed to heat, characterized in that the resin layer is exposed to heat imagewise, the resin layer is then electrostatically charged and the electrostatic latent image by means of known methods of electrophotography makes visible and, if necessary, fixed. © 209 659/84 9.