DE1288913B - Recording material for the production of deformation images - Google Patents

Description

Another thermoplastic registration mode 15 generated and then developed in the air is described in an article by WEGlenn (Journal of Can, Eliminating the Requirement of Vacuum Applied Physics, Vol. 30, No. 12, December 1959,
Pp. 1870 to 1873). That is where the film exists
from a multi-layer structure that has a high-melting layer support, one on top of the layer ao
more sluggish, transparent, conductive layer and
contains a low-melting, thermoplastic layer lying on the conductive layer. Of the
Multi-layer film is placed in a vacuum chamber

brought, in which an electron gun is built. as draws, chamber and the need to bring the recording material into and out of this remove, be turned off.

The subject matter of the invention is based on recording materials composed of a thermoplastic layer and optionally a support for the production of deformation images on electrophotographic Ways out and is therefore

A charge image is created on the surface of the thermoplastic film by guiding the Electron beam applied over the surface. The film is then set to the melting point of the Thermoplastic fabric is heated, which creates the electrostatic forces between the charges on the Film and the conductive layer allows the surface of the thermoplastic layer where the Charges sit, depressing, until these forces are in equilibrium with the surface counter-tension are located. The film is then cooled below the melting point of the thermoplastic material, and the deformations remain in the solidified surface. The deletion is carried out by Heat the film to a temperature well above the melting point in the absence of any Achieved charge image, in which case the surface tension compensates for the deformation; The movie is then ready for reuse. According to the indications of this publication, the movie becomes ordinary in the vacuum chamber to develop the deformations by inducing current in the transparent, conductive layer is heated. To view the thermally developed images is a modified optical streak system required.

One form of eidophore for astronomical observation is described by HW B ab cock (Journal of the Optical Society of America, Vol. 48, No. 7, July 1958) in which the variable optical element is a thin, uniform, flexible, rigid film is of low but finite electrical conductivity. A reflective coating that the thermoplastic layer contains gas bubbles, is opaque and is covered with a thermoplastic protective layer or that the thermoplastic layer consists of a crystalline wax or crystalline plastic, is opaque and is covered with a top layer of a crystalline wax or crystalline plastic or
that the thermoplastic layer contains a dye and is applied to a layer which contains a compound which reacts with the dye to give a reaction product different in hue, lightness and / or saturation, or

that the thermoplastic layer with a - preferably specular - reflective top layer is covered and contains less fusible particles or on a layer that contains such particles, is applied or that the thermoplastic layer with a Upper layer of an optionally colored vinyl polymer is covered and on a Layer is applied which contains a reacting with the vinyl polymer Zn compound.

In a particularly advantageous embodiment of the recording materials, the more difficult to melt Contain particles, these particles consist of di- or ferroelectric crystals.

In a particularly advantageous embodiment of the recording materials that have a layer made of vinyl polymer and have a layer containing a Zn compound, is the vinyl polymer Polyvinyl acetate and the Zn compound

Aluminum is attached to one side of the film, and the other side is tessellated
coated by insulated collecting elements. The So Zinc Oxide. The film is built into a cathode ray tube, which for the production of the deformation images is first equipped with a transparent window instead of the usual one according to a known screen, whereby the aluminum method on a recording-coated side of the thin film according to the invention produces an outwardly material. After generating one is directed. The other side of the film then receives a charge image on the dielectric, for example a grid charge which is applied to the mosaic by the electron gun of the cathode ray tube according to the invention, carrying a charge image. The resulting electrostatic drawing material is briefly used by known means

to a temperature above the melting point of one of the constituents of the recording material heated to develop the image seen by the naked eye and in simple optical devices can be used.

As can be seen from the above, the heat developable according to the invention have Recording materials for producing visible images which correspond to the charge images applied to the film, generally a plurality of Layer structure made of a layer carrier, an outer, continuous, optically smooth top layer and an intermediate layer comprising the means on the recording material prior to heating an optical characteristic of a given type and the parts corresponding to the charge image to give a contrasting characteristic after heating. At least the outer one Layer has a melting point lower than that of the other layers. With some ao Embodiments of the invention are the outer layer and the intermediate layer not by any sharp border separated and therefore have the same melting point. The substrate is in Conductive to an extent sufficient for the image transfer process and preferably but not necessarily transparent. In some cases the support can be removed from the rest of the recording material can be removed after its development, if this remaining recording material is self-supporting. In such cases the support can be a metal plate. The invention Recording materials have different shapes for different uses. At a Form is a preferably, but not necessarily, transparent support made of a suitable one Material is present on which there is a conductive layer and an outer layer of a transparent, dielectric material which has a melting point lower than that of the other layers is. A charge image generated on the surface of the dielectric material is after applying heat in the form of roughened areas lying on a smooth surface, made visible.

The protective layer advantageously exists in the case of recording materials containing gas bubbles made of a normally transparent, low-melting resin and the underlying Layer of the same resin that contains many small gas washes that make the film opaque (usually white) do. After applying heat, the resin in the two layers melts, and that Recording material is in the charge-bearing areas by the electrostatic forces compressed, and the vesicles collapse, forming a transparent image in one Leave behind an opaque substrate.

In the case of recording materials with a top layer and a thermoplastic layer Wax or resin with a polycrystalline structure that is usually opaque, resulting in a diffuse appearance Refraction of light leading to the interfaces of the crystals makes the surface tension lowered of the melted layers, which correspond to the areas of the charge image electrostatic The crystals are subjected to forces that make them amorphous when heat is applied. The picture then appears as a transparent area in an opaque background.

In one embodiment of the recording materials containing a color component these have a resin layer with a smooth surface, under which further such material is located which contains small capsules filled with a color-forming material. One The intermediate layer contains a chemical reagent that reacts with the color-forming material. To Heating above the melting point of the resin forms a colored image in the areas in which the electrostatic forces are sufficient to collapse the capsules of the color-forming Material to cause the color-forming material to react with the chemical reagent is released.

Another such recording material includes an outer continuous layer of a Resin and a layer of a compound, wherein the resin and the compound are interconnected Formation of a color change can react. The two layers are covered by a very thin one Intermediate layer separated from another fusible resin. When heated, this intermediate layer becomes melted, and as a result of the electrostatic forces permeates resin from the outer continuous layer the melted thin intermediate layer and comes with that with it reacting compound in contact, thereby producing a colored image visible to the eye.

In the case of recording materials containing less fusible particles, in which a Layer of fusible resin which contains harder fusible particles embedded and with another layer of fusible resin, which only forms an optically smooth surface, is covered, flows under the action of heat and electrostatic forces in the heated image areas the resin of the smooth surface layer under the more difficult-to-melt particles, so that they adhere to the Step surface. This gives an image of a roughened or grainy consistency on a smooth surface.

Is an upper continuous layer made of a thermoplastic resin and an intermediate layer from the same thermoplastic resin in which elongated, dielectric or ferroelectric particles, Arbitrarily oriented, dispersed, are present, that is what is made possible by heat The alignment of the particles melts in the electrostatically charged image areas in the electrostatic field, what the light transmission that normally passes through the arbitrary oriented particles is prevented, thereby creating a photographically transparent image arises.

The recording materials according to the invention can be used for all purposes, for deformation images resulting recording materials are usually used, commercially exploit. They are particularly suitable for micro image storage, data bit recording and Display devices and also for hard copy applications.

The recording materials according to the invention achieve that now on electrophotographic Ways thermoplastic deforma-

tion images can be generated in the air and developed in the air, so that the requirement There is no need to work in a vacuum.

It is also possible according to the invention to produce halftone images as well as creating line art. The images generated can be used without special optical systems which is another significant benefit. In addition, the recording materials according to the invention for the

which the recording material 10 a suitable heat source, such as a combination an infrared lamp 20 and a reflector 22. The layer 14 is through the Lamp 20 is heated to a temperature slightly above the melting point, whereupon the surface tension and the electrostatic forces of the charges cause a change in the surface, such as shown on line 15. Due to the

Direct Photographic applicable, whereby the ver io surface changes in the loaded image reversal of powders and powder treatment devices a visible image appears,

without and without the need to use powder and powder developing devices would be to bring parts into vacuum chambers and

and the associated problems of contamination of the devices avoided will.

For further explanation and to make it easier to remove 15 from these.

Achieving the full advantages of the invention in FIG. 3 and the following figures is a

In practice, preferred embodiments of the invention are given below merely as examples

Larger section of the recording materials shown. On the left is the recording material before development by heating and

descriptions. In these shows 20 fixing is shown by cooling, and on the right-

F i g. 1 the generation of a charge image on the th page is an area after as an example

the machining according to the invention.

A recording material 30 according to the invention is shown in FIG. 3 shown. This contains a layer

3 shows a recording medium 12 according to the invention and a layer 32, which is an upper layer material containing a vesicle-filled heart, 34 with a smooth top surface 38 and a F i g. 4 shows an intermediate recording layer 36 according to the invention, which is filled with gas bubbles, material containing crystalline wax or resin. The top surface 38 is smooth and continuous-F i g. 5 another recording according to the invention. In contrast to the porous nature of the intermediate material, the capsules filled with dye for 30 layer 36. Otherwise the layer 32 is homogeneous, and it

in detail with reference to the drawing

a recording material according to the invention,

F i g. 2 the heating stage in the development of a charge image,

there is no particular dividing line between layers 34 and 36. Layer 32 can pass through uniform, full exposure of a film of bubbles to UV light that creates bubbles that making the film white and translucent. An example of such a layer is polyvinylidene chloride containing a diazo compound. The substrate 12 consists of a transparent material that can be conductive or

contains the reaction with a color-forming material,

F i g. 6 shows another recording material according to the present invention, in which a fusible resin film contains embedded, difficult to melt particles,

F i g. 7 shows another recording material according to the invention which comprises two reactive materials which separated by a thin layer of fusible resin, contains, and

F i g. 8 a further recording 4 ° according to the invention on which a conductive film can be applied, tion material that a fusible, a dispersion The substrate 12 is, for example, a poly elongated, dielectric or ferroelectric, ethylene terephthalate film, and the conductive surface, Resin containing randomly oriented particles which is capable of generating the charge in accordance with the required image consists of one

F i g. 1 illustrates the creation of an electro-transparent 45 aluminum coating. Static images can also be used on a transparent, conductive coating or a drawing material 10 which is a transparent conductive glass material according to the invention. If a layer support 12 with a transparent, conductive transparency is not required, then an appropriate layer 13 and a layer 14 can be used, the moderate amount of which is a metal support. Melting point is lower than that of the layer 50 Some of the recording media according to the invention. An example of the substrate 12 is materials which are self-supporting and can be removed after the polyethylene terephthalate, and the conductive layer 13 development from the substrate 12, for example a thin aluminum overlay. In such cases a metal substrate should be used. If desired, a known form of well-suited. After the charge image on the conductive glass take the place of the combination. 55 recording material is transferred and subsequently examples for the layer 14 are ester resins (with ßend the recording material is heated, effected or without plasticizer), coumarins, maleic anhydride resins, silicone varnishes, petroleum waxes and
Polyethylene. A charge image is generated on an electro-

Photographic plate 16, which contains a metal 60 clear through the layer 32 in these areas and the layer base 18 and a selenium layer 19, becomes transparent, irrespective of whether this produces small areas in the usual way. That on the selenium layer
The charge image appearing in 19 is transferred to the recording material 10. Methods and devices for transferring charge images at the level of the electrostatic charge generated dielectric material are known. will. The layer support 12 can be transparent,

The development of the charge image on what the developed recording material in the Drawing material 10 is shown in Fig. 2, with changed image areas transparent and in the

g,

the surface tension coincides with the electrostatic forces of the charges of the bubbles in the charged image areas, where-

p ggg,

of a line image or extensive areas of a two-dimensional image. Halftone images can according to the invention by image-wise differentiation

Makes background areas opaque. The layer carrier 12 can, however, also be opaque and colored, for example black, red, blue or the like. So that the image is colored in the changed image areas and in the Areas of the background appear white. Alternatively, the recording material 30 may be a Support 12, a conductive coating or layer 13 and a further double layer included, which consists of a foam or sponge layer 36 made of chemically foamed polyvinyl chloride paste or by means of Freon foamed polyurethane foam and a smooth or homogeneous one Upper layer 34 consists of the same material.

In this embodiment there is actually no sharp boundary between the layers, the only measure is that preferably, but not necessarily, the top surface 38 is smooth and continuous in contrast to the "spongy" surface that is otherwise would appear. An example of a different recording material 30 according to the in Fig. 3 shown arrangement consists of a polyethylene terephthalate layer support 12 with a Thickness of about 0.13 mm, on which there is an aluminum layer 13 on which a Layer of foamed resin is applied.

Another recording material 40 according to the invention is shown in FIG. 4 shows that a layer support 12 and a film layer 42, which consists of a double layer in which a layer 44 crystalline wax or resin crystals containing arbitrary structure and the other layer 46 containing crystals of the same material but of a structure forming a smooth top surface 48. As in In the previous embodiment, there is no particular dividing line between the layers. The layer support 12 can again, as described above, be transparent or opaque, if necessary be black or otherwise colored. If a charge image is generated on the recording material and then heated, the crystals in the charged image areas melt and become amorphous and therefore translucent. In contrast to the uncharged image areas from as before crystalline resin or wax let the light through the charged areas.

An example of a material suitable for this embodiment is crystalline polyethylene.

F i g. 5 shows a further recording material according to the invention 50, which is a substrate 12, a top layer 52, which is a resin film encapsulated with Contains color former, and an intermediate layer 56 with a reactive with the color former Having fabric. The cover layer 58 of the top layer 52 is smooth. If there is a charge image on the Recording material is generated and the recording material is heated, so the electrostatic Forces and the surface tension in the charged areas of the image coincide of the color former capsules, which leads to a reaction with the said substance in the intermediate layer 56 below Formation of an area with contrasting optical properties that is visible to the naked eye is, leads.

The encapsulation of color formers and the formation of optically contrasting markings after being broken by the pressure of a pen or type are known. The invention relates, however the application of heat and electrostatic forces to break the capsules. With regard to the details, reference is made to German patents 1209 999.1243 643, where It should be noted that the materials and methods described there are taken into account the reactions relating to heat and electrostatic forces to carry out the present Invention should be selected.

Another recording material 60 according to the invention is shown in FIG. 6 shown. In this embodiment According to the invention, there is a layer 62, comprising a meltable resin, on a substrate 12 and a conductive layer 13. The layer 62 has a layer portion 64, the embedded contains difficult-to-melt particles 65. All particles 65 are under a cover layer 66, so that the top surface 68 is optically smooth and somewhat removed from the particles 65. The meltable resin melts when exposed to heat, and the electrostatic forces and the reduction of the Surface tension pulls surface 68 below the tips of the charged areas Particles 65 down as shown on the right-hand side of the figure, with a roughened surface, as at 15 in FIG. 2 is formed.

The particles of the refractory material can be powdered or crushed glass, magnesium acetate, magnesium sulfate and the like. The index of refraction should be comparable for the resin and the particles. For example, one can use lightweight flint glass, the refractive index (s) of which is in the range 1.605 to 1.572, with polystyrene, which has a refractive index of 1.59. Polyethylene (rt = 1.51) works well together with common crown glass (n = 1.532 to 1.511) and acrylate (n = 1.49 to 1.51). Other combinations are also possible, for example polyvinyl acetate (ra = 1.46 to 1.5) and magnesium acetate (η = 1.49), which should not be too finely ground. Polyvinyl acetate and magnesium sulfate in one of its forms can also be used. The last-mentioned substance has a refractive index of 1.495 to 1.514 in a form with 5 mol of water of crystallization. In its usual form with 4MoI water of crystallization, it has a refractive index of 1.508 to 1.522 and is pink in color, which can discourage its use. Acrylate and albite glass (= 1.489) are also suggested.

The particles 65 can also react with a chemical substance with a change in color. This chemical reagent is after the heat generation and fixation by cooling on the surface applied to only the exposed particles 65 to form the desired contrast to dye.

F i g. 7 shows yet another embodiment of the invention, which relates to a recording material 70 comprising a layer support 12, a layer 72 of a resin such as a vinyl resin and a layer 74 of a zinc compound, for example Zinc oxide, covered by a very thin layer 76 of fusible resin, which is preferably white or transparent are separated. The electrostatic forces and the heat cause the very thin layer 76 of fusible resin melts and the vinyl resin is in contact with the Zinc compound comes, with an area with con-

909 506/1454

test optical properties remains in the charged image areas. Is it for example around zinc oxide and vinyl resin, the developed charged areas are black what a very effective image that can be seen with the naked eye is, results. For this embodiment of the invention, for example, the reaction also comes between Dimethylglyoxime and nickel (II) chloride are possible.

Another recording material 80 according to the invention is shown in FIG. 8 shown. This recording material 80 includes a substrate 12, a conductive layer 13 and a layer of one fusible resin 82 having a top cover layer 84 and an intermediate layer 86 of a fusible Resin containing a dispersion of elongated dielectric crystals. Enable here the electrostatic forces and the heat orient the crystals in the direction of the electrostatic Field of the image charges, creating an ao optical contrast in the charged image areas against the background. An example of crystals for this embodiment is calcium citrate, which is in the form of elongated, white needles. The refractive indices play a role in this embodiment not matter. Those in the resin such as polyethylene are randomly oriented Crystals make the recording material quite opaque and more light passes through when the Crystals are aligned, but not nearly as much contrast is achieved as some of the other embodiments. Polarized light can be used to improve the contrast will.

Claims (7)

Claims: 35 1. Recording material composed of a thermoplastic layer and optionally one Support for the production of deformation images by electrophotographic means, characterized in that the thermoplastic Layer contains gas bubbles, is opaque and with a thermoplastic protective layer is covered. 2. Recording material composed of a thermoplastic layer and optionally one Support for the production of deformation images by electrophotographic means, thereby characterized in that the thermoplastic layer consists of a crystalline wax or consists of crystalline plastic, is opaque and has a top layer of a crystalline wax or crystalline plastic is covered. 3. Recording material composed of a thermoplastic layer and optionally one Support for the production of deformation images by electrophotographic means, thereby characterized in that the thermoplastic layer contains a dye and on a Layer is applied, the one with the dye to one in hue, brightness and / or Contains saturation different reaction product reacting compound. 4. Recording material composed of a thermoplastic layer and optionally one Support for the production of deformation images by electrophotographic means, thereby characterized in that the thermoplastic layer with a - preferably reflective - reflective top layer is covered and contains or difficult to melt particles a layer containing such particles is applied. 5. Recording material according to claim 4, characterized in that it is heavier fusible particles containing elongated di- or ferroelectric crystals. 6. Recording material composed of a thermoplastic layer and optionally one Support for the production of deformation images by electrophotographic means, thereby characterized in that the thermoplastic layer with a top layer of an optionally colored vinyl polymer is covered and applied to a layer that has a Contains a Zn compound which reacts with the vinyl polymer. 7. Recording material according to claim 6, characterized in that it is a vinyl polymer Contains polyvinyl acetate and zinc oxide as a Zn compound. 1 sheet of drawings