DE2063324A1 - - Google Patents

Description

Patent attorneys Dipl.-Ing. F. Veickmann,

Dipl.-Ing. H.Weickmann, Dipx.-Phys. Dr.K. Fincke D1PL.-ING. F. A. Weickmänn, Dipl.-Chem. B. Hüber

S MUNICH 86, DEN

XEROX COEPORATIOH ", post office box 860820

Xerox Square, möhlstrasse 22, phone number 4g S9 21/22

Rochester, NYT4605 / USA <9S392i / 22>

Image transfer method

The invention relates to a method for transferring a removable, in particular dielectric, image from one. insulating recording medium on a non-conductive receiving surface.

Various imaging methods are already known in which a thin film of material is applied to a recording surface in order to distribute one image-wise thereon To create contrast. With regard to the process steps carried out in generating such images the recording surface on which the image is generated, in some cases not very durable, can be used advantageously or otherwise inexpensive.

One known from the British patent Ϊ I50 $ 81 Imaging process works with a multilayer structure, which is a thin film of an insulating or having semiconducting material. In this imaging process, an image-forming layer is formed by applying a Layer of an electrically photosensitive imaging material formed on a pad. In one embodiment, this image-forming layer contains a light-sensitive

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union substance, for example metal-free phthalocyanine _Ψ dispersed in a cohesively soft insulating or dielectric binder. The base coated in this way is also referred to as the donor surface. If necessary, the image-forming layer can be made cohesive-soft. The process step of softening the image layer is referred to as activation and is carried out in most cases by the action of a swelling agent, solvent or partial solvent for the image-forming layer or by heating the layer. A receiving surface is placed on the surface of the image generation layer and an electric field is generated on the image material layer, while irradiation with a Lieht shadow pattern takes place in accordance with the image to be reproduced. When the donor sheet is separated from the receiver sheet, the image material layer breaks along the lines determined by the light-shadow pattern of the radiation. Part of the image layer is transferred to one of the sheets while the remainder remains on the other sheet, so that a positive image, ie a duplicate of the original, is produced on one sheet while a negative image is produced on the other «

In many cases, in a facility that is after the Multi-layer works, a donor sheet and a Receipt sheet used for the intended use of the generated image are not well suited. A transfer of the images from one surface to another without Image quality loss has heretofore been difficult and required expensive and complicated devices.

Another example of known imagery where the transfer of the image material from a surface to the other performed is electrophotography * Bei Most electrophotographic processes will be one through a toner-generated image of a dielectric structure

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Drawing surface containing an electrostatic image, transferred to a receiving surface that forms a usable copy. The one required to carry out this image transfer The device is also constructed in a complicated manner.

The object of the invention is to provide a method for To create image transfer from one base to another that avoids the disadvantages mentioned above and works with the simplest possible devices, the image quality should not be reduced.

A method of the type mentioned is designed according to the invention to achieve this object in such a way that the Surface of the image and the recording medium is charged to an image transfer voltage that the image with the receiving surface is brought into contact that between the exposed sides of the recording surface and the Receiving surface an electrically conductive connection is formed, whereby the exposed sides on the same Potential are brought, and that the receiving surface of the recording area is separated at this potential.

The image transfer according to the invention thus takes place by charging the image surface and the image carrier surface. That so charged image is then brought into contact with the non-conductive receiving surface, thereby forming an image transfer arrangement results. A conductive connection is then made between the outer surfaces of the recording surface and the Receiving area made. This is usually done by touching the free surfaces with conductive plates, which are connected to each other by a wire. This connection makes both surfaces one and the same Potential brought, and the removable image is transferred to the receiving surface. If the image transmission

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arrangement results in a high quality image on the receiving surface. "Image" should also include parts of images and understood to be delimited or artificial patterns of dielectric material on a substrate.

According to the invention, the image is electrically charged and this charge is held by the image forming material until the image transfer is complete. In this way, the method according to the invention is particularly suitable for transferring such Images are suitable in which the imaging material is electrically insulating, so that an electrical charge is held for at least a short time. The most varied of insulating substances can be used in the process according to the invention be used. Such substances are, for example, polyethylene, polypropylene, polyamides, polymethacrylates, polyacrylates, Polyvinyl chlorides, polyvinyl acetates, polystyrene, polythioloxanes, chlorinated rubber, polyacrylonitrile, epoxy resins, Phenolic resins, hydrocarbon resins and other natural resins such as rosin derivatives as well as mixtures and copolymers these substances. Images that are particularly suitable for the method according to the invention are those that contain insulating materials contain, which hold a charge and are or can be made detachable. Such substances are microcrystalline Waxes like Sunoco 1290, Sunoco 5825, Sunoco 985, all available from the Sun Oil Company; Paraflint RG available from the Moore and Munger Company; Paraffin waxes such as Sunoco 5512, Sunoco 3425 available from Sun Oil Company; Sohio Parowax available from dsr Standard Oil Company of Ohio, Hydrogenated oil waxes from Capitol City 1380 are available from Capitol City Products Company, Columbus, Ohio; Caster Wax L-2790 available from Baker Caster Oil Company; Vitikote L-340 available from Duro Commodities; Polyethylene such as Polyethylene DYJT, Polyethylene DYLT, Polyethylene DYDT, all available from Union Carbide Corp .; Marlex TR 822, Marlex 1478, available from Phillips Petroleum Company; Epolene C-13, Epolene 0-10,

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available from Eastman Chemical Products Company; Polyethylene AC8, Polyethylene AC612, -Polyethylene AC324, available from Allied Chemicals; modified styrenes such as Piccotex 75, Piccotex 100, Piccotex 120, available from Pennsylvania Industrial Chemical; Vinyl acetate-ethylene copolymers such as Elvax Resin 210, Elvax Resin 420, available from E.I. DuPont de Nemours & Co., Inc., Vistanex MH, Vistanex L-80 available from Enjay Chemical Company; Vinyl chloride-vinyl acetate copolymers such as Vinylite VYL] ?, available from Union Carbide Corp .; Styrene vinyl toluene

Copolymers; Polypropylenes and mixtures of these substances. |

Recently, a photoelectrophoretic imaging process was developed in which electrically light-sensitive pigment substances for generating images under the influence of light in an electric field. The one after this Process-produced images consist of particles of electrically photosensitive substances that hold an electrical charge can. Such a process is known, for example, from US Pat. No. 3,384,565, which were produced according to it Images can be transmitted by the method according to the invention.

The materials used in multilayer imaging are more fully detailed in the British patent 1 150 381 described. Both of the above imaging methods use electrically photosensitive Substances that are also insulating and can therefore hold an electrical charge. Pictures taken after this Processes can be transferred from a recording medium to a receiving sheet if the method according to the invention is applied. On the other hand, insulating imaging materials that are not electrically contain light-sensitive substances, also according to the

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Invention to be transferred.

The surface of the insulating image forming material and the support surface of the recording medium become electrical charged to a voltage required for image transfer. The amount of charge depends in part on the dielectric constant, the charge polarity and the thickness of the imaging material. Furthermore, it changes with the Di-, electricity constant and the thickness of the image carrier layer and the receiving surface. Becomes a material with extremely high Dielectric constant is used, lower voltages are possible, for example from about 200 to about 400 volts. If, on the other hand, materials with a very low dielectric constant are used, higher voltages are required, up to a value which, however, is below the electrical breakdown voltage of the recording medium.

In general, an image transfer voltage is applied to the Imaging material and the recording surface turned on. This voltage has a minimum value, which is for different substances are different and required for image transfer.

In general, the image transmission voltage is calculated according to the following formula:

^V L

Vr is a constant voltage for the imaging material, IL. is the dielectric constant of the imaging material, Kj is the dielectric constant of the recording surface, K is the dielectric constant of the receiving surface, IK is the bead of the recording surface,

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D is the thickness of the, receiving surface and
Dr is the thickness of the imaging material. If the recording surface and the receiving surface each have a thickness of 0.025 mm and an equal dielectric constant of 3.25, and the imaging material has a dielectric constant of 5 and a thickness of 0.005 mm, the calculated image transfer voltage is 4000 volts, the voltage constant for the imaging material being 240 volts is.

If the image from the recording surface is not removable, so λ, an activation step in the inventive method is inserted advantageous. The activation can take place in various ways, for example by heating the image-forming layer and the associated reduction in adhesion or by applying a substance to the surface of the image-forming material or by incorporating a substance in the image-forming material that reduces the adhesive force of the image-forming material on the recording surface. The substance is called an "activating agent". The activation agent should preferably have a high specific resistance in order to avoid an electrical flashover in the image transmission arrangement. It is therefore generally beneficial to clean commercially available activating agents, which removes impurities that generate higher conductivity. This can be achieved by passing the liquids through a clay filter column or by using other suitable cleaning methods. Generally speaking, the activating means should consist of a material suitable for springs which has the aforementioned properties. In the following, an activating agent is to be understood as meaning not only those substances that are usually referred to as solvents, but also those that are partially solvent

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agents, swelling agents or softening agents for the image forming material are. The activating agent can be added at any suitable point within the process prior to ! Separation of the layer arrangement ". .._ ■ __—- ■■

In general, it is favorable if the activating agent has a relatively low boiling point, so that a fixation of the image-size inoculation surface is achieved by evaporation of the activating agent. The fixation should take place as quickly as possible with at most a slight warming. However, the invention is of course not limited to such relatively volatile activating agents. Activating agents with a very high boiling point can also be used, for example silicone oils such as dimethylpolysiloxanes and Tangkettige aJL ± = ~~~ "^>-" ~~ Phatic hydrocarbon oils with a very high boiling point, which are normally used as transformer oils, for example. Jemco-0 transformer oil available from Westinghouse Electric Company. Such substances can also be used successfully in the process according to the invention. Although these less "vei4u & s ^ dS | iH3iIM agents are not removed by evaporation, image fixation can be achieved by touching the image with an absorbent sheet, such as paper, which sucks off the activating liquid. Any suitable evaporative or Typical activating agents are Sohio Odorless Solvent 34-4-0, an aliphatic (kerosene) hydrocarbon component available from the Standard Oil Company of Ohio, carbon tetrachloride, petroleum ether, Preon 214 (tetrafluorotetrachloropropane), other halogenated hydrocarbons, perchlorethylene , Trichloromonofluoromethane, trichlorotrifluoroethane, trichlorotrifluoromethane, ither such as diethyl ether,

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Diisopropyl ether, dioxane, tetrahydrofuran, ethylene glycol monoethyl ether, aromatic and aliphatic hydrocarbons such as benzene, toluene, xylene, hexane, cyclohexane, gasoline, benzine and petroleum, vegetable oils such as coconut oil, babussu oil, - palm oil, olive oil, castor oil Dodecane and mixtures of these substances. Sohio Odorless Solvent 3 ² WO is preferably used because of its odorlessness, as it is non-toxic and has a relatively low ignition point.

The recorder suitable for the method according to the invention The carrier should hold an electrical charge for at least a short time and is therefore referred to as insulating. Substances that are suitable as recording media have = eiaejä == greater electrical resistance and are therefore electrical insulators. Typical insulation materials have one

14 · Specific resistance over approx. 10 Ohm cm at normal temperatures. Typical examples of such substances are polyethylene, polypropylene, polyethylene terephthalate, cellulose acetate, paper, plastic-coated paper such as polyethylene Jibjjrjj ^ jejjjy ^ JE & pj ^^ = vinyl chloride-vinylidene chloride copolymers and mixtures of these substances. Mylar (an acid by condensation reaction between ethylene glycol and terephthalic {polyester formed from EI DuPont de Nemours & Co., Inc.) is preferably used because of its durability and excellent insulating properties.

Any suitable electrically non-conductive material can be used for the receiving surface in the method according to the invention will. Materials that have a specific resistance of over 10 ohm cm at normal temperatures. Typical non-conductive substances are those above for the recording medium mentioned and additionally impregnated with metals

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Plastics such as Stabilenfilm, available from Keuffel and Eater. As already stated, the outer surfaces of an image generation arrangement formed from recording medium, image generation material and receiving surface are at the same potential brought. A common way of compensating for this is to use a to deposit electrically conductive layer and this conductive layer to connect to a similar conductive layer behind the recording surface. This image transmission arrangement is then separated while the two ■ conductive layers are electrically connected to each other, or the assembly can be separated after removing the conductive layers.

Static charges can be applied to dielectric layers in a known manner, for example by touching the image and the recording medium with an electrically charged electrode. Furthermore, the layer can be charged with a corona discharge device, for example of the type mentioned in US Pat. Nos. 2,588,699, 2,777,957, 2,885,556. Also, conductive rollers of the US Patent 2,297,691, or other suitable arrangements can be applied to US Patent 2 980 83 ⁷ J or friction devices according to the invention.

The conductive layers used can be made of any suitable conductive material and flexible or be rigid. (Typical conductive materials are metals such as aluminum, brass, steel, copper, nickel, zinc etc. Furthermore, metallic coatings on plastic substrates can be conductive by including a suitable material Made rubber and similar materials are used »Leifcbaren Rubber is preferably used because of its flexibility. Transparent conductive electrodes, for example

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Glass coated with tin oxide can be used, but are not required, since the present invention Image transmission does not require light. If a photoconductive material is used, the electrical charge can pass through Exposure to light can be derived.

The invention is described below with reference to an embodiment shown in the figures. Show it:

1a is an enlarged sectional view of an image transmission arrangement before equipotential bonding between the free surfaces and

1b shows a sectional view of the image transmission arrangement after equipotential bonding between the free surfaces, whereby the image transmission results.

FIGS. 1 a and 1 b show enlarged representations of the invention Process, in the actual execution, the individual elements are in contact with each other, namely in the order shown in FIGS. 1 a and 1 b.

In Fig. 1 a, a releasable imaging material 2 is between an electrically insulating recording medium 4- and an electrically non-conductive receiving surface 6 is arranged. This arrangement is located between conductive Layers 8 and 10. Before the imaging material 2 and the recording medium 4 are inserted into the arrangement, they are electrically charged positively with respect to the upper surface of the recording medium 4-, the negatively charged is. In Fig. 1 b shows how in the case of a desired image transmission, an electrical connection between the conductive layer 8 and the conductive layer 10 with a line 12 via a switch 14 is produced. Fig. 1b shows the image forming material 2 adhered the receiving surface 6, so that the recording medium 4 x from

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Imaging material is exempt.

The following examples serve for further specific explanation of the method according to the invention. They represent some preferred embodiments of the invention. Parts and percentages relate to weight, unless otherwise stated.

EXAMPLES I TO IV

First, images are made from a dielectric material, that can hold an electrical charge. This image generation is carried out as follows: A commercially available, Metal-free phthalocyanine is first purified by leaching in acetone to remove organic impurities. Since this leaching gives the less sensitive crystalline beta-form, the X-form becomes after that in Example I. in U.S. Patent 3,357,989. The X-phthalocyanine thus obtained is used in the following manner to prepare the image-forming layer: 5 g Sunoco 1290, a microcrystalline wax with a melting point of 81 ° C, are dissolved in 100 ecm reagent petroleum ether, which is heated to 50 ° 0. Then they are quenched by immersing the container in cold water, creating small wax crystals arise. 5 g of the cleaned and ground Phthalocyanines are then added to the wax paste along with 0.3 l of clean porcelain balls and poured into a 0.6 1 large grinding jar filled. This mixture is then milled in the dark at 70 rpm for 3 1/2 hours, and then 20 ecm Sohio, Solvent 3440 are added. This paste is then placed on a 0.025mm thick Mylar sheet with a # 12 wire-wound spreader stick in dim green light applied, which after drying creates a 2.5 micron thick coating (Example I). The same paste is made on three further Mylar foils up to a layer thickness of 1.5 microns

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with a spreader stick No. 8 (Example II), 5 microns with a spreader stick # 24- (Example III), and 7.5 microns with a spreading stick # 26 (Example IV). Each of the coatings is then heated to about 60 ° C in the dark to dry. Then the dried donor surfaces are applied to the tin oxide surface of NESA glass plates with their layers facing away from the tin oxide layer. A receiving sheet of 0.025 mm thick Mylar is then placed on the coated surface of each dispenser. A sheet of black electrically conductive paper is then placed on the receiver sheet, completing the image transfer assembly. The receiver sheet is then raised and the phthalocyanine wax layer is activated with a quick stroke of a wide camel hair brush soaked in Sohio Odorless Solvent. The receiver sheet is then reloaded and a roller is slowly passed once over the closed assembly, applying gentle pressure to remove excess activator. The positive terminal of an 8000 volt DC voltage source is then connected to the NESA coating via a 5500 megohm resistor, while the negative terminal is connected to the black, opaque electrode and grounded. When the λ voltage is switched on, a light image generated with a white incandescent lamp is projected upwards through the NESA glass, for which purpose Wollensak magnifying optics 90 mm / f 4.5 at approx. 27 lux and an exposure time of 0.1 second are used, whereby this results in a total light energy of 2.7 Luxsec. After the exposure, the receiving sheet is detached from the arrangement, the voltage source still remaining on. The remaining small amount of activating agent evaporates within approx. 1 second after (separation of the sheets, after which two excellent images result. A duplicate of the original is on the donor sheet, the reverse is present on the receiving sheet.

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Each of the images obtained on the Mylar film as a recording medium by the method described above is Immediately after its creation applied to a G, 025 mm thick Mylar film. This is located on an aluminum sheet, a second aluminum sheet is placed on the recording medium. Then use a short piece of copper wire Spring clips attached to each aluminum sheet. Immediately thereafter, the recording medium and the receiving sheet separated by hand. Each of the four images generated in the manner described above is then a total of the Mylar receiving || sheet transferred with the Mylar recording medium free of visual material has become. The pictures on the Mylar receiving sheets are held in place by gently heating the imaging material to remove excess activator «All images transferred in this way have the density and resolution of that on the Mylar recording medium generated initial image.

Example V

First, an image is produced by a multicolor photoelectrophoretic process of the type described in US Pat. No. 3,384,565, for which 8% by weight of an image suspension are produced with equal proportions of the following pigments: Watchung Red B, a barium salt of 1- (4 '-Methyl-5 ¹ -chlorazobenzene-2-sulphonic acid) -2-hydroxy-3-naphthenic acid OINr. 15865; Monolite Fast Blue GS, the alpha-form metal-free phthalocyanines, CINr. 74-100 and 1-gyan-2,3-phthaloyl-7i8-benzpyrrocoline, obtained after synthesis according to the first method on page 1215 in the Journal of the American Chemical Society of March 5, 1957. The article is entitled "Reactions of Naphthoquinones with Malonic Ester and its Analogs III 1-substituted Phthaloyl and Phthaloyl Benzopyrrocolines "from Pratt et al. These pigment substances have the. Colors magenta, cyan and little hides your _e ©

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Mixture is applied to a 0.025 mm thick Mylar sheet and prepared for photoelectrophoretic imaging. It is exposed to an electric field by the sheet with the layer side up on the conductive one Surface of a glass plate and this with a Switches, a voltage source and the conductive core of a roller is connected in series with a coating made of baryta paper. The roll has a diameter of approx. 6.5 cm. A multicolored positive The transparent image is projected through the glass plate onto the ternary mixture by placing it between the image | pulp suspension and a white light source is placed while the roller is over the surface of the coated Glass plate is rolled. The roller carries a negative voltage of 4000 volts in relation to the conductive glass plate. It the roller is moved three times, the roller is cleaned between each movement. After the three operations there is a fully colored image of excellent quality and perfect color separation on the mylar film. The electric field and the exposure are maintained during the entire movement of the roller. After shutdown the tension from the NESA glass plate becomes a electrically insulating fine paper placed on the image, which is on the surface of the mylar film. One * Para rubber electrode is placed on the paper and connected to the conductive surface of the glass plate. Direct after this connection, the paper and the para-rubber electrode are removed from the mylar sheet. That before The image on the Mylar film now adheres to the fine paper and can be changed by applying a transparent Polymer coating are fixed.

Example VI

A black imaging layer used for multilayer imaging is suitable, is achieved by combining approx.

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5 g of the X form of phthalocyanine with approx. 5 g of Algol Yellow GC, 1,2,5,6-Di- (C) C'-diphenyl-Cthiazol-anthraquinone, C.I.Nr. 67300, available from General Dyestuffs Corporation), and about 2.8 grams of purified Watchung Red B, 1- (4'-methyl-5 ~ chlor-2-sulfonic acid) azobenzene-2-hydroxy-J-naphthenic acid, C.I.No. 15865 available from E.I. DuPont de Nemours & Co., approx. 8 g Sunoco Microcrystalline Grade 5825 with an ASTM melting point of 66 ° C, available from Sun Oil Company, and about 2 grams of Paraflint RG, a paraffinic material with low Molecular weight available from Moore & Munger Company, New York City. Approx. 320 ml petroleum ether (90 - 120 ° C) and Approx. 14 ml Sohio Odorless Solvent 3440 are mixed with the Pigments placed in a glass vessel containing 13 mm flint balls. The mixture is then made by rotating the glass jar ground at approx. 70 rpm for approx. 16 hours. Then it is heated to approx. 4-5 ° C for approx. 2 hours and then again cooled to room temperature. The paste-like mixture is then reduced to 0.025 mm in dim green light strong mylar film applied with a spreader stick no.22,

p resulting in a layer weight of approx. 2.9 g / m. The so The image layer produced on the Mylar film is made in the multilayer imaging process with a conductive aluminum sheet used as a reception area. The field strength applied during image generation and the subsequent separation of donor and receiver sheets is 1400 volts per 0.01 mm. In this way, a positive image is created on the mylar sheet, it is with the residual tension on the imaging material and the Mylar sheet with a 0.05 mm thick Tedlar sheet brought into contact, which has the dielectric constant 9 and is deposited with a conductive metal layer. The Mylar recording medium has a dielectric constant of 3.25. A sheet of conductive rubber is placed on the mylar sheet and an electrical connection is established with the conductive layer of the Tedlar film. The mylar

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is removed from the Tedlar foil together with the conductive rubber peeled off, whereby the picture now remains on the Tedlar foil.

Example VII

Another image is formed by the multilayer process using an imaging layer of the type described in Example VI Kind is used. A multilayer assembly comprising a 0.025 mm thick Mylar donor sheet, the black imaging material, and a 0.025 mm Mylar receiver sheet Strength is built. The one prevailing during image formation and the subsequent separation of donor and receiver sheets Field strength is 1600 volts per 0.01 mm. After imaging, the mylar receiver sheet is placed on another mylar sheet 0.025 mm thick, which is wetted with Sohio Odorless Solvent 34-4-0. A conductive rubber sheet is made placed on the top of the Mylar film provided with the picture and connected to a conductive plate, which is behind the wetted mylar sheet. After the image is firmly in contact with the wetted mylar sheet, the rubber electrode and mylar receiver sheet are removed, leaving the image on the wetted mylar sheet.

In all of the above examples one obtains through the inventive Process a right-sided copy by * placing an appropriate number of mirrors in the image generation optical device used is provided. The use of mirrors for imaging provides a compensation factor which generates a laterally correct image when it is transmitted according to the method according to the invention.

Although in the above description of preferred embodiments of the invention, certain proportions and amounts of substance were mentioned, other substances of the above

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specified type can be used if the results are similar. Furthermore, further additives can be provided which have a synergistic, improving or otherwise favorable effect on the properties of the imaging material. For example, different dyes, spectral Sensitizers, types of particles composed of two or more layers, mixtures of substances, compositions and electrical Sensitizers such as Lewis acids in the imaging material be added.

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Claims (9)

Sponsorship claims (λ J method for transferring a detachable, in particular dielectric, image from an insulating recording medium to a non-conductive receiving surface, characterized in that the surface of the image (2) and of the recording medium (4) is charged to an image transmission voltage that the image (2) is brought into contact with the receiving surface (6) so that an electrically conductive connection (12) is formed between the exposed sides of the recording surface (4) and the receiving surface (6), whereby the exposed sides are brought to the same potential, and that the Receiving surface (6) is separated from the recording surface (4) at this potential. 2. The method according to claim 1, characterized in that the image (2) can be removed by applying an activating agent is made. 3. The method according to claim 1 or 2, characterized in that that the image transmission field strength is in the range of approx. 400 V / 0.01 mm up to a value below the breakdown field strength of the recording medium (4). 4. The method according to any one of claims 1 to 5, characterized in, that a thermoplastic material is used as the recording medium (4). 5. The method according to any one of claims 2 to 4, characterized in that that an at least partial solvent for the image (2) is used as an activating agent. 109826/1628 6. The method according to any one of claims 1 to 5, characterized in that that as the image transmission voltage from the Imaging remaining stress is used. 7. The method according to any one of claims 1 to 6, characterized in that the receiving surface (6) is a thermoplastic Material is used. 8. The method according to claim 6, characterized in that an image generated by the multilayer process (2) is used will. 9. The method according to claim 6, characterized in that a generated by the photoelectrophoretic imaging process Image (2) is used. 109826/1628