US3245785A - Graphic reproduction - Google Patents

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US3245785A
US3245785A US251129A US25112963A US3245785A US 3245785 A US3245785 A US 3245785A US 251129 A US251129 A US 251129A US 25112963 A US25112963 A US 25112963A US 3245785 A US3245785 A US 3245785A
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United States
Prior art keywords
copy sheet
light
image
conductive
reproduction
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US251129A
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Carl S Miller
Byron W Neher
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3M Co
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Minnesota Mining and Manufacturing Co
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Priority claimed from US809134A external-priority patent/US3082085A/en
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    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G17/00Electrographic processes using patterns other than charge patterns, e.g. an electric conductivity pattern; Processes involving a migration, e.g. photoelectrophoresis, photoelectrosolography; Processes involving a selective transfer, e.g. electrophoto-adhesive processes; Apparatus essentially involving a single such process
    • G03G17/02Electrographic processes using patterns other than charge patterns, e.g. an electric conductivity pattern; Processes involving a migration, e.g. photoelectrophoresis, photoelectrosolography; Processes involving a selective transfer, e.g. electrophoto-adhesive processes; Apparatus essentially involving a single such process with electrolytic development
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03CPHOTOSENSITIVE MATERIALS FOR PHOTOGRAPHIC PURPOSES; PHOTOGRAPHIC PROCESSES, e.g. CINE, X-RAY, COLOUR, STEREO-PHOTOGRAPHIC PROCESSES; AUXILIARY PROCESSES IN PHOTOGRAPHY
    • G03C1/00Photosensitive materials
    • G03C1/705Compositions containing chalcogenides, metals or alloys thereof, as photosensitive substances, e.g. photodope systems
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G13/00Electrographic processes using a charge pattern
    • G03G13/22Processes involving a combination of more than one step according to groups G03G13/02 - G03G13/20
    • G03G13/24Processes involving a combination of more than one step according to groups G03G13/02 - G03G13/20 whereby at least two steps are performed simultaneously
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G17/00Electrographic processes using patterns other than charge patterns, e.g. an electric conductivity pattern; Processes involving a migration, e.g. photoelectrophoresis, photoelectrosolography; Processes involving a selective transfer, e.g. electrophoto-adhesive processes; Apparatus essentially involving a single such process
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G5/00Recording members for original recording by exposure, e.g. to light, to heat, to electrons; Manufacture thereof; Selection of materials therefor
    • G03G5/02Charge-receiving layers
    • G03G5/04Photoconductive layers; Charge-generation layers or charge-transporting layers; Additives therefor; Binders therefor

Definitions

  • This invention relates to a graphic reproduction system.
  • this invention relates to a process involving the directing of a light-image of an original onto a photosensitive surface and permanently altering the light-struck areas of said surface to provide the desired reproduction.
  • the process is applicable to direct photography as Well as to the reproducing of printed matter, sketches, paintings or other documents, and is operable with infrared, actinic light, ultraviolet light, X-rays and other means of radiation.
  • the process of the present invention is capable of producing a completed permanent graphic reproduction simultaneously with exposure to the corresponding light-image and without the subsequent application of chemical developing and fixing solutions. While appearing in some respects much more comparable to certain electrostatic copy processes than to those concerned with silver halide reactions, the present invention avoids the use of developing powders or dusts and instead relies on physical or chemical means to provide the desired reproduction on a photosensitive surface.
  • the object of this invention is to provide a new and useful reproduction system.
  • Yet another object is to provide a new reproduction composition.
  • Another object of this invention is to provide a dry process for the reproduction of images or copying of printed matter and the like.
  • Another object of this invention is to provide a process which directly reproduces the image or directly copies upon exposure to the object to be reproduced and does not necessarily require a separate step of developing.
  • Yet another object of this invention is to provide a process which utilizes actinic light to reproduce a permanent image on a suitable carrier without a separate fixing step to make the image permanent.
  • Another object is to provide a new copy or reproduction paper.
  • a carrier or support containing an irradiation-sensitive composition is exposed to an irradiation source, such as through a negative, to produce an image or pattern in latent form.
  • an irradiation source such as through a negative
  • the latent image on the exposed reproduction carrier is subjected to a high potential gas ion discharge which develops the image visibly.
  • the ion dis charge consists essentially of normally gaseous ions which are negatively charged.
  • the source of the gas ion discharge is a corona which is connected to a negative source of direct current.
  • the carrier of the reproduction composition is grounded or connected to a positive source of direct current.
  • the bombardment of the surface of the reproduction carrier with the negatively-charged gas ions from the corona source reproduces the image as the result of a differential conductive pattern in the areas of the irradiation-sensitive materials which have been exposed to the image source and which as a result show either more or less resistivity to the conduction of the ions to the ground or to the positive terminal.
  • the gas ions from the corona discharge hit the surface of the photosensitive material at those points of highest conductivity (least resistivity) and cause a chemical reaction or a decomposition of the image-forming composition resulting in a change in color or light value.
  • No aerosol material or other matter, such as dyes, are necessary in the environmental atmosphere.
  • the sole material which bombards the reproduction carrier is normally gaseous ions, such as oxygen of the air.
  • a critical aspect of this invention is the use of a negatively-charged electrode. Image formation Will not result if the electrode or corona is positively charged or grounded and the reproduction carrier negatively charged.
  • the carrier upon which the image is reproduced contains an electrically-conductive base, such as metal, upon which the irradiation-sensitive material, such as a photoconductor, is placed or bonded thereto.
  • Other chemicals as hereinafter defined may be included as a part of the composition on the conductive carrier.
  • the irradiation-sensitive material on the carrier is the only conductor present other than the electrically-conductive base. Any binders or other chemicals introduced into the system must be non-conductors as at least compared with the conductivity of the irradiation-sensitive material in its most conductive state. It is important in a relative sense that the irradiation-sensitive material, such as a photoconductor, is the only material capable of conduction under the conditions of ion discharge on the surface of the conductive base.
  • Exposure to the light-image and to the electrical discharge may take place simultaneously or the electrical discharge may be applied subsequent to exposure to the light-image.
  • the light-struck areas of a White or lightcolored copy paper may be darkened, as in forming a positive print from a photographic negative transparency; or the light-struck areas of a dark-colored copy paper may be lightened in color, as in forming a direct positive reproduction of an opaque original.
  • Metal foil paper laminate is a suitable carrier or base material.
  • Metal conductors such as aluminum, chromium, nickel and copper, are suitable as the conductive material on the carrier.
  • Other conductive sheet material may be substituted for the foil paper laminate.
  • Aluminum foil or other metal foils alone are excellent conductors but are expensive and unpleasant to handle.
  • Paper, plastic films, or other poorly conductive carriers or flexible sheets or films may be rendered adequately conductive by surface-coating with aluminum or other metal applied in vapor form under vacuum. In some cases, particularly under conditions of high humidity, many papers or films are adequately conductive without further treatment.
  • One example is regenerated cellulose film (cellophane) which carries a content of glycerine or like moisture absorbing material.
  • Non-conductive sheets or films have been found useful, where of sufiicient thinness, by pressing them into close uniform contact with a conductive base.
  • the combination of the non-conductive thin plastic film and a metal foil base is useful as a carrier material for the sensitive coating.
  • the sensitive coating is also applicable to various articles other than thin sheets or films, including metal plates, clock faces or instrument dials, etc.
  • photoconductor and electrically conductive carrier may be shown to be photoelectro-sensitive by connecting the conductive paper-or the conductive base or clamp to which it is attachedto the source of potential through a sensitive current-measuring device, and noting any change in current occurring with change in illumination of the copying paper surface.
  • the value of the current is observed to change abruptly when the previously unlighted photoelectro-sensitive copying paper is illuminated. Most such sheets show an increase in current flow on illumination; others show a decrease. Both types are useful.
  • the irradiation-sensitive agents which may be used in accordance with this invention include the photoconductors, such as anthracene, anthraquinone, sulfur, zinc sulfide, yellow cadmium sulfide, zinc oxide, a mixture of zinc oxide, zinc sulfide and cadmium sulfide, a mixture of zinc and cadmium sulfide, titanium dioxide, barium titanate, selenium, bismuth trioxide, lead oxide and mercuric oxide. Mixtures of the above photoconductors may be effectively used without departing from the scope of this invention. All of these materials show a change in conductivity or resistivity upon exposure to irradiation.
  • non-conductive organic dyes such as Victoria Green WB Crystals (a triphenylmethane dye, Color Index 657), Calcozine Red BX (Color Index 749), Erie Red 43 (Color Index 448), Congo Red (an azo dye), and Pontachrome Blue ECR (Color Index 722); and oxidation-reduction indicators such as diphenylamine, diphenylbenzidine, N,N-diethyl p-phenylene diamine or its hydrochloride, diphenyl guanidine, diphenyl urea, pand o-phenylene diamine, and p-phenetidine.
  • these dyes are oxidizable under the conditions of gas ion discharge. These materials either react or decompose to effect the color change.
  • the thickness of the image-reproducing composition on the surface of the carrier or conductive base will be between about 0.5 and about 8 mils. In case separate materials are used, such as a photoconductor and a dye, these materials may be admixed and placed upon the carrier as a mixture or they may be placed upon the carrier in layers. However, the layer adjacent or in contact with the electrically conductive base must be the photoconductive material.
  • the thickness of the carrier, including the electrical conductor, when in paper form will be between about 2 and about 50 mils in thickness, generally less than mils in thickness.
  • the exposure time used to reproduce the image will vary to a considerable extent and will depend primar-ly upon the type and intensity of the light or irradiation source, the sensitivity of the image-reproducing composition and/or upon the sensitivity of the photoconductor. In general, the time of exposure will vary between about 0.01 and about 30 minutes.
  • the image-reproducing composition and the sheet material made therefrom should be conditioned in the dark before exposure and should not be exposed to the light prior to exposure for reproducing the image.
  • the exposure of the image-reproducing composition to the gas ion discharge to develop the latent image will be between about 0.01 and about 120 minutes, usually less than 30 minutes, and may be done simultaneously with the initial exposure to the image.
  • FIGURE 1 diagrammatically illustrates typical apparatus employed in making a reproduction of a photographic transparency or the like.
  • FIGURE 2 indicates a cross-section of a representative form of irradiation-sensitive copy paper.
  • the sensitive copy sheet 10 comprising an outer photoconductive layer 11 and an electrically conductive backing or carrier 12, such as a paper-aluminum foil laminate, is supported against a suitable base 13 with the conductive carrier 12 connected to ground.
  • An electrode 14 is supplied with high voltage (at least 1000 volts, preferably at least 10,000 volts) from a source 15 which is also grounded, the system providing a high potential gradient and an ion discharge in the direction of the copy sheet 10.
  • Actinic light or other type irradiation from a source 16 is directed by a concave mirror 17 through the transparent areas of a photographic negative or other suitable graphic original 18 to produce a light image which is focused, by means of a stop 19 and a lens 2i), on the irradiation-sensitive surface 11 of the sheet 10.
  • the light-image produced in the lamp and lens system is focused on the sensitive surface 11 of sheet 10, which at the same time is subjected to the gas ion discharge from point electrode 14.
  • a visible image is rapidly produced on the sensitive surface.
  • the sheet is first exposed to the light-image with the electrode removed, and the electrode is subsequently replaced and voltage applied to develop the copy.
  • Typical apparatus which has been employed in procedures as just described includes a conventional photoprojector employing a 500-watt lamp and an F.4.5 lens having a focal length of three inches, the projector being at a distance of about twenty inches from the Hat base 13.
  • a photographic transparency e.-g. a lantern slide, is used as the transparency 18.
  • the electrode 14 is a sharp-ended small-diameter steel wire, the point being located centrally of the picture area and at a distance of about one to four inches, preferably about two inches, from the face of the copy paper 10.
  • the negative lead of a conventional DC is a conventional DC.
  • the term light as applied to the radiation provided from the projector 10 will be understood to include monochromatic light and various invisible radiations as well as the white light ordinarily employed for image projection.
  • Ultraviolet light in the neighborhood of 3600 Angstroms wave length, has proven particularly suitable; and radiations of still higher frequency, such as X-rays and radiations from radioactive sources, are also useful under somewhat different but analogous condition.
  • the radiation used must be capable of producing the required differential-conductive effect at the receptor surface containing the compound which undergoes a change in light value.
  • the single corona point source 14 shown in FIGURE 1 may be replaced by a network of points or line sources of corona, and such network may be caused to move across the light-beam in order to avoid the formation of shadows on the sensitive sheet, to permit the printing of larger areas, to provide a more uniform corona and to accelerate the speed of reproduction.
  • Particulate irradiation-sensitive materials such as zinc oxide are preferably applied as dispersions. in small amounts of water-insoluble non-conductive film, forming binders, as shown in the examples.
  • the binder holds the particles to the conductive backing and appears to aid in insulating the particles from each other and prevents the gas ions from dissipation over the entire surface.
  • Small amounts of a non-conductive binder, just suflicient to form a Well-bonded, rub-resistant coating provide maximum potential differential at the coated surface and are preferred.
  • Useful copying papers may be produced in which the dispersion is distributed within the fibrous sheet, or in which the irradiation-sensitive particles are incorporated in the sheet, in the substantial absence of binder, during the formation of the paper from the fibrous wood or cloth pulp.
  • the binder layer may first be applied to the conductive film or sheet and the particulate irradiation-sensitive material adhered to the surface; or a surface film of sensitive material may be formed, e.g. by vapor or solvent deposition of selenium; or by converting surface films of zinc or cadmium to sulfide form by appropriate chemical treatment.
  • Non-conductive Waterresistant soaps such as zinc stearate or cobalt palmitate, are included to improve the smoothness or eliminate the graininess of the coated surface, to improve the adhesion of the coating to metal surfaces, or to minimize the effects of soluble salts or other materials present in the sheet, or to alter the sensitivity of the sheet to light of various wave lengths.
  • Example 1 A mixture of 55 parts by weight of photoconductive zinc oxide (Mercks Reagent grade), 5 parts of chlorinated rubber binder (Parlon, 125 cps. grade), and 40 parts of toluene (solvent) are ground in a pebble mill for 3-4 hours until a smooth dispersion is obtained. The dispersion is spread over the metal surface of a laminate of thin aluminum foil and paper, in a uniform layer and at a thickness of 3 mils (0.003 inch), and the solvent removed by evaporation at moderately elevated temperature. The coated surface is then swabbed with a 5% solution of diphenylamine in ethanol, and dried at room temperature. The thus sensitized sheet is white in appearance and remains substantially unchanged on exposure to normal light although some discoloration takes place on prolonged aging.
  • photoconductive zinc oxide Mercks Reagent grade
  • 5 parts of chlorinated rubber binder Parlon, 125 cps. grade
  • solvent toluene
  • the sheet is supported on the flat base of a printing apparatus as described in connection with FIGURE 1 of the drawing, and connection is made between the aluminum foil layer and the paper-holding clamps, which are provided in this case with serrated or saw-tooth edged jaws capable of penetrating the sensitive surface coating to the aluminum foil.
  • a light image through a photographic negative transparency is focused on the paper, which is otherwise in subdued light, and the power supply is turned on. After approximately thirty minutes expo sure, the light-struck areas are found to be deep blue in color. The remainder of the surface remains white or a very faint blue tint.
  • Example 2 A conductive laminate a employed in Example 1 is coated with a 2-mil thickness of a smooth ball-milled blend of 48 parts by weight of zinc oxide, 4 parts of a resinous copolymer of butadiene and styrene (Pliolite 8-5) as a binder, and 48 parts of toluene as a solvent, and dried.
  • the coated surface is swabbed with a 1% solution of Calcozine Green V dye in ethanol, and again dried. The sheet has a faint green appearance.
  • the sheet is exposed to a light image formed through a photographic positive transparency while being subjected to corona discharge, as previously descnibed.
  • the sheet is converted to a permanent dark green color at the lightstruck areas.
  • Example 3 A 2-mil smooth coating of a uniform mixture of 50 parts powdered yellow bismuth trioxide (Bakers CP grade), 5 parts chlorinated rubber, and 4-5 parts toluene is provided on a paper-aluminum foil laminate and dried to produce a pale yellow-colored sensitive copying paper. Exposure for about five minutes under the conditions previously described produces a permanent black image corresponding to the light-struck areas, on the yellow background. Some further darkening of the image occurs on continuing the exposure to fifteen minutes or somewhat longer, and without observable darkening of background areas.
  • the time required for developing the permanent image is substantially reduced, images having been developed within an exposure time of ten seconds without difiiculty.
  • One such sensitized composition is 50 parts of Bi O 5 parts of ceric steaiwate, 5 parts of chlorinated rubber (Parlon), and 40 parts of toluene (solvent).
  • Example 4 The sensitivity of the color change occurring in the sensitive copying paper of Example 3 is increased by applying a thin coating of the bismuth trioxide dispersion over a primary coating of zinc oxide as provided in Example 1.
  • Example 5 Barium titanate is substituted for the bismuth trioxide in the two-layer coated sheet of Example 4.
  • the copying paper which is stable on exposure to bright daylight, is converted from an initial white or faint pink color to a black appearance on exposure to light and corona discharge under the conditions described. The image is retained for several days both in the light and in the dark.
  • Titanium dioxide is equally as effective as the barium titanate in the production of an image on exposure to ion discharge in the presence of a light image, and the resulting image is stable on prolonged storage.
  • Example 6 The sensitizing coating in this example is formed of a uniform mixture of 50 parts yellow lead oxide, 5 parts chlorinated rubber, and 45 parts toluene, applied to a paper-metal foil laminate at a uniform thickness of 3 mils and dried. Exposure for fifteen minutes produces a mildly black image of the light-struck areas on a yellow background.
  • Example 7 A conductive backing coated with a thin dried layer of a dispersion of a zinc; cadmium sulfide phosphor powder (in this case, New Jersey Zinc Co.s No. 2220) in a polymeric binder is surface-treated with a variety of dyes to form sensitive copying papers useful in the practice of this invention. Typical dyes are Victoria Green WB, Calcozine Green V and Calcozine Red BX.
  • the light first activates the photoelectro-sensitive particles, producing in said particles either a decrease or, more commonly, an increase in the conductivity of the particle.
  • the high potential gradient establishes an electrostatic force across the photoelectro-sensitive layer. Any resulting charges at conductive areas of the surface are neutralized by conduction to or from the conductive backing or supporting plate; but such action cannot occur, at least to the same extent, at non-conductive areas, and hence a differential potential pattern, corresponding to the nonlighted areas, is established on the exposed surface.
  • the corona set up at the high potential source causes ionization of the surrounding air, and particles or ions resulting from such ionization and carrying a suitable charge are drawn toward the oppositely charged areas of the reproduction paper.
  • Chemical action or decomposition of the reactive components within or on the surface of the reproduction paper, resulting in the development of the image, is caused by the presence of reactive atoms, such as oxygen, or the high energy level at the surface of the reproduction, or by the presence of free electrons.
  • Example 1 evidence in support of the above theory in the chemical action is oxidation and is found in the observed fact that the sheet material of Example 1 is inoperable in the photocopying method described when the air normally surrounding the high potential source is replaced by oxygen-free nitrogen. Diphenylamine is converted from light green to dark green by oxidation. It appears likely, therefore, that oxygen ions are responsible for the color change produced in Example 1; and such ions are known to be produced by corona discharge in air. Corona discharge may also produce ions of ozone and of oxides of nitrogen when produced in air, and other ions when produced in other ionizable gases or mixtures of gases. Reactants which undergo a suitable visible change on reaction with such ions are contemplated, therefore, as photodeveloper components for the photoelectro-sensitive coatings of the reproduction papers of this invention.
  • the light image is formed on the sensitive surface by focusing the light passing through a transparent original such as a lantern slide.
  • the light image may be formed by reflection from an opaque printed surface or from an original article, by methods commonly employed in photography.
  • the light may be filtered through various colored filters for separating colored images into monochromatic components.
  • a method for reproduction of a graphic original comprising projecting the graphic original upon a photoconductive copy sheet comprising a metal layer upon which has been bonded thereto a photoconductive layer containing a photoconductor and containing at least one organic compound selected from the group consisting of organic dyes and oxidation-reduction indicators which undergoes a change in color when subjected to a high potential negative ion bombardment to produce a differential conductive pattern comprising relatively non-conductive and relatively conductive areas on the surface thereof corresponding to said graphic original, establishing a high potential gradient between said copy sheet containing said differential conductive pattern and a negative corona electrode in the presence of an ionizable atmosphere, said electrode being positioned from said copy sheet such that the conductive areas of said copy sheet are bombarded with negatively-charged normally gaseous ions, and continuing said bombardment of said copy sheet with said negatively-charged normally gaseous ions for a suflicient length of time to produce a visible reproduction of said graphic original upon the surface of said copy sheet as the result
  • a method for reproduction of a graphic original comprising projecting the graphic original upon a photoconductive copy sheet comprising a metal layer upon which has been bonded thereto a photoconductive layer containing an inorganic photoconductor and at least one organic compound selected from the group consisting of organic dyes and oxidation-reduction indicators which undergoes a change in color upon oxidation when subjected to a high potential oxygen ion bombardment created by a corona discharge to product a differential conductive pattern comprising relatively non-conductive and relatively conductive areas on the surface thereof corresponding to said graphic original, establishing a high potential gradient between said copy sheet containing said differential conductive pattern and a negative corona electrode in the presence of an oxygen-containing atmosphere, said electrode being positioned from said copy sheet such that substantially the entire conductive areas of said copy sheet are bombarded with negativelycharged oxygen ions, and continuing said bombardment of said copy sheet with said negatively-charged oxygen ions for a sufiicient length of time to produce a visible reproduction of said graphic original upon the surface of

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Description

l 1966 c. s. MILLER ETAL 3,245,785
GRAPHIC REPRODUCTION Original Filed April 27, 1959 'IIIIIIIIIII, Oufer ,a/wfara/vaucf/i/e /a ye/? @2 m Conducf/ue (arr/er.
//Vl/E/V 7025 6424 5. M/L 1. 52 5mm NEHE/P United States Patent 3,245,785 GRAPHIC REPRODUCTION Carl S. Miller, St. Paul, Minn., and Byron W. Neher, Hudson, Wis., assiguors to Minnesota Mining and Manufacturing Company, St. Paul, Minn., a corporation of Delaware Original application Apr. 27, 1959, Ser. No. 809,134, now Patent No. 3,982,085, dated Mar. 19, 1963. Divided and this application Jan. 14, 1963, Ser. No. 251,129
8 Claims. (Cl. 961) This application is a division of our prior and co pending application S.N. 809,134, filed April 27, 1959, now Patent No. 3,082,085.
This invention relates to a graphic reproduction system. In one aspect this invention relates to a process involving the directing of a light-image of an original onto a photosensitive surface and permanently altering the light-struck areas of said surface to provide the desired reproduction.
The process is applicable to direct photography as Well as to the reproducing of printed matter, sketches, paintings or other documents, and is operable with infrared, actinic light, ultraviolet light, X-rays and other means of radiation. Unlike silver halide photography, the process of the present invention is capable of producing a completed permanent graphic reproduction simultaneously with exposure to the corresponding light-image and without the subsequent application of chemical developing and fixing solutions. While appearing in some respects much more comparable to certain electrostatic copy processes than to those concerned with silver halide reactions, the present invention avoids the use of developing powders or dusts and instead relies on physical or chemical means to provide the desired reproduction on a photosensitive surface.
The object of this invention is to provide a new and useful reproduction system.
Yet another object is to provide a new reproduction composition.
Another object of this invention is to provide a dry process for the reproduction of images or copying of printed matter and the like.
Another object of this invention is to provide a process which directly reproduces the image or directly copies upon exposure to the object to be reproduced and does not necessarily require a separate step of developing.
Yet another object of this invention is to provide a process which utilizes actinic light to reproduce a permanent image on a suitable carrier without a separate fixing step to make the image permanent.
Another object is to provide a new copy or reproduction paper.
Various other objects and advantages Will become apparent to those skilled in the art from the accompanying description and disclosure.
According to this invention a carrier or support containing an irradiation-sensitive composition is exposed to an irradiation source, such as through a negative, to produce an image or pattern in latent form. Simultaneously or thereafter, the latent image on the exposed reproduction carrier is subjected to a high potential gas ion discharge which develops the image visibly. The ion dis charge consists essentially of normally gaseous ions which are negatively charged. The source of the gas ion discharge is a corona which is connected to a negative source of direct current. The carrier of the reproduction composition is grounded or connected to a positive source of direct current.
The bombardment of the surface of the reproduction carrier with the negatively-charged gas ions from the corona source reproduces the image as the result of a differential conductive pattern in the areas of the irradiation-sensitive materials which have been exposed to the image source and which as a result show either more or less resistivity to the conduction of the ions to the ground or to the positive terminal. The gas ions from the corona discharge hit the surface of the photosensitive material at those points of highest conductivity (least resistivity) and cause a chemical reaction or a decomposition of the image-forming composition resulting in a change in color or light value. No aerosol material or other matter, such as dyes, are necessary in the environmental atmosphere. The sole material which bombards the reproduction carrier is normally gaseous ions, such as oxygen of the air.
A critical aspect of this invention is the use of a negatively-charged electrode. Image formation Will not result if the electrode or corona is positively charged or grounded and the reproduction carrier negatively charged.
The carrier upon which the image is reproduced contains an electrically-conductive base, such as metal, upon which the irradiation-sensitive material, such as a photoconductor, is placed or bonded thereto. Other chemicals as hereinafter defined may be included as a part of the composition on the conductive carrier. The irradiation-sensitive material on the carrier is the only conductor present other than the electrically-conductive base. Any binders or other chemicals introduced into the system must be non-conductors as at least compared with the conductivity of the irradiation-sensitive material in its most conductive state. It is important in a relative sense that the irradiation-sensitive material, such as a photoconductor, is the only material capable of conduction under the conditions of ion discharge on the surface of the conductive base.
Exposure to the light-image and to the electrical discharge may take place simultaneously or the electrical discharge may be applied subsequent to exposure to the light-image. The light-struck areas of a White or lightcolored copy paper may be darkened, as in forming a positive print from a photographic negative transparency; or the light-struck areas of a dark-colored copy paper may be lightened in color, as in forming a direct positive reproduction of an opaque original.
Metal foil paper laminate is a suitable carrier or base material. Metal conductors, such as aluminum, chromium, nickel and copper, are suitable as the conductive material on the carrier. Other conductive sheet material may be substituted for the foil paper laminate. Aluminum foil or other metal foils alone are excellent conductors but are expensive and unpleasant to handle. Paper, plastic films, or other poorly conductive carriers or flexible sheets or films may be rendered adequately conductive by surface-coating with aluminum or other metal applied in vapor form under vacuum. In some cases, particularly under conditions of high humidity, many papers or films are adequately conductive without further treatment. One example is regenerated cellulose film (cellophane) Which carries a content of glycerine or like moisture absorbing material. The use of a transparent plastic film upon which is deposited a thin transparent layer of metal conductor is advantageous, so that the corona discharge and the light image is applied from opposite sides of the carrier or film to produce an effective copy or transparency while avoiding any possibility of shadows resulting from the electrode.
Non-conductive sheets or films have been found useful, where of sufiicient thinness, by pressing them into close uniform contact with a conductive base. The combination of the non-conductive thin plastic film and a metal foil base is useful as a carrier material for the sensitive coating.
The sensitive coating is also applicable to various articles other than thin sheets or films, including metal plates, clock faces or instrument dials, etc.
Any combination of photoconductor and electrically conductive carrier may be shown to be photoelectro-sensitive by connecting the conductive paper-or the conductive base or clamp to which it is attachedto the source of potential through a sensitive current-measuring device, and noting any change in current occurring with change in illumination of the copying paper surface. The value of the current is observed to change abruptly when the previously unlighted photoelectro-sensitive copying paper is illuminated. Most such sheets show an increase in current flow on illumination; others show a decrease. Both types are useful.
The irradiation-sensitive agents which may be used in accordance with this invention include the photoconductors, such as anthracene, anthraquinone, sulfur, zinc sulfide, yellow cadmium sulfide, zinc oxide, a mixture of zinc oxide, zinc sulfide and cadmium sulfide, a mixture of zinc and cadmium sulfide, titanium dioxide, barium titanate, selenium, bismuth trioxide, lead oxide and mercuric oxide. Mixtures of the above photoconductors may be effectively used without departing from the scope of this invention. All of these materials show a change in conductivity or resistivity upon exposure to irradiation. Certain of these mater-ialsnamely bismuth trioxide, titanium dioxide, barium titanate and lead oxide-are themselves capable of providing a visible change on simultaneous exposure to light and gas ion discharge without the use of a color-changing agent. Others, such as zinc oxide, are not visibly affected, but a latent image may be formed, and sensitive coatings employing this and similar photoconductive materials must, therefore, be provided with color-changing or photo-developer agents for imparting the desired permanent visible change. For this purpose, many effective materials have been found. These include non-conductive organic dyes, such as Victoria Green WB Crystals (a triphenylmethane dye, Color Index 657), Calcozine Red BX (Color Index 749), Erie Red 43 (Color Index 448), Congo Red (an azo dye), and Pontachrome Blue ECR (Color Index 722); and oxidation-reduction indicators such as diphenylamine, diphenylbenzidine, N,N-diethyl p-phenylene diamine or its hydrochloride, diphenyl guanidine, diphenyl urea, pand o-phenylene diamine, and p-phenetidine. Preferably, these dyes are oxidizable under the conditions of gas ion discharge. These materials either react or decompose to effect the color change.
The thickness of the image-reproducing composition on the surface of the carrier or conductive base will be between about 0.5 and about 8 mils. In case separate materials are used, such as a photoconductor and a dye, these materials may be admixed and placed upon the carrier as a mixture or they may be placed upon the carrier in layers. However, the layer adjacent or in contact with the electrically conductive base must be the photoconductive material. The thickness of the carrier, including the electrical conductor, when in paper form will be between about 2 and about 50 mils in thickness, generally less than mils in thickness.
The exposure time used to reproduce the image will vary to a considerable extent and will depend primar-ly upon the type and intensity of the light or irradiation source, the sensitivity of the image-reproducing composition and/or upon the sensitivity of the photoconductor. In general, the time of exposure will vary between about 0.01 and about 30 minutes. The image-reproducing composition and the sheet material made therefrom should be conditioned in the dark before exposure and should not be exposed to the light prior to exposure for reproducing the image. The exposure of the image-reproducing composition to the gas ion discharge to develop the latent image will be between about 0.01 and about 120 minutes, usually less than 30 minutes, and may be done simultaneously with the initial exposure to the image.
In most instances, no fixing or inactivation of the image-forming composition is necessary when viewed under ordinary actinic light conditions. However, this will depend upon the sensitivity of the composition to actinic light. If the image-forming composition is sensitive to actinic light, removal or inactivation of the imageform-ing composition may be necessary, such as by washing off the unreacted materials. These compositions described herein are usually not sufficiently sensitive to ordinary light to cause darkening of the background or fading of the image.
The invention will be further described in connection with the accompanying drawing. FIGURE 1 diagrammatically illustrates typical apparatus employed in making a reproduction of a photographic transparency or the like. FIGURE 2 indicates a cross-section of a representative form of irradiation-sensitive copy paper. The sensitive copy sheet 10, comprising an outer photoconductive layer 11 and an electrically conductive backing or carrier 12, such as a paper-aluminum foil laminate, is supported against a suitable base 13 with the conductive carrier 12 connected to ground. An electrode 14 is supplied with high voltage (at least 1000 volts, preferably at least 10,000 volts) from a source 15 which is also grounded, the system providing a high potential gradient and an ion discharge in the direction of the copy sheet 10. Actinic light or other type irradiation from a source 16 is directed by a concave mirror 17 through the transparent areas of a photographic negative or other suitable graphic original 18 to produce a light image which is focused, by means of a stop 19 and a lens 2i), on the irradiation-sensitive surface 11 of the sheet 10.
In making a copy, for example of an original in the form of a photographic transparency such as a microfilm slide, the light-image produced in the lamp and lens system is focused on the sensitive surface 11 of sheet 10, which at the same time is subjected to the gas ion discharge from point electrode 14. A visible image is rapidly produced on the sensitive surface. Alternatively, with copy paper of suitable properties, the sheet is first exposed to the light-image with the electrode removed, and the electrode is subsequently replaced and voltage applied to develop the copy.
Typical apparatus which has been employed in procedures as just described includes a conventional photoprojector employing a 500-watt lamp and an F.4.5 lens having a focal length of three inches, the projector being at a distance of about twenty inches from the Hat base 13. A photographic transparency, e.-g. a lantern slide, is used as the transparency 18. The electrode 14 is a sharp-ended small-diameter steel wire, the point being located centrally of the picture area and at a distance of about one to four inches, preferably about two inches, from the face of the copy paper 10. The negative lead of a conventional DC. power supply at a potential of 15-25 'kilovolts is connected to the electrode 14; the positive terminal is grounded or is connected directly to the conductive backing of the copy paper 10', which is suitably supported on the flat base 13. The apparatus is maintained in darkness or in subdued light during the copying procedure.
The term light as applied to the radiation provided from the projector 10 will be understood to include monochromatic light and various invisible radiations as well as the white light ordinarily employed for image projection. Ultraviolet light, in the neighborhood of 3600 Angstroms wave length, has proven particularly suitable; and radiations of still higher frequency, such as X-rays and radiations from radioactive sources, are also useful under somewhat different but analogous condition. In all cases, the radiation used must be capable of producing the required differential-conductive effect at the receptor surface containing the compound which undergoes a change in light value.
The single corona point source 14 shown in FIGURE 1 may be replaced by a network of points or line sources of corona, and such network may be caused to move across the light-beam in order to avoid the formation of shadows on the sensitive sheet, to permit the printing of larger areas, to provide a more uniform corona and to accelerate the speed of reproduction.
Particulate irradiation-sensitive materials, such as zinc oxide, are preferably applied as dispersions. in small amounts of water-insoluble non-conductive film, forming binders, as shown in the examples. The binder holds the particles to the conductive backing and appears to aid in insulating the particles from each other and prevents the gas ions from dissipation over the entire surface. Small amounts of a non-conductive binder, just suflicient to form a Well-bonded, rub-resistant coating, provide maximum potential differential at the coated surface and are preferred. Useful copying papers may be produced in which the dispersion is distributed within the fibrous sheet, or in which the irradiation-sensitive particles are incorporated in the sheet, in the substantial absence of binder, during the formation of the paper from the fibrous wood or cloth pulp. On the other hand, the binder layer may first be applied to the conductive film or sheet and the particulate irradiation-sensitive material adhered to the surface; or a surface film of sensitive material may be formed, e.g. by vapor or solvent deposition of selenium; or by converting surface films of zinc or cadmium to sulfide form by appropriate chemical treatment.
Other materials may be included with the photoelectrosensitive material, in these various constructions, for a variety of purposes. For example, non-conductive Waterresistant soaps, such as zinc stearate or cobalt palmitate, are included to improve the smoothness or eliminate the graininess of the coated surface, to improve the adhesion of the coating to metal surfaces, or to minimize the effects of soluble salts or other materials present in the sheet, or to alter the sensitivity of the sheet to light of various wave lengths.
Specific illustrative but non-limitative examples of sensitive copying papers which have been found useful in the process hereinbe-fore described will now be given, together with further details of their application to the reproduction of light images. Proportions appearing in these examples are given in parts by weight, unless otherwise stated.
Example 1 A mixture of 55 parts by weight of photoconductive zinc oxide (Mercks Reagent grade), 5 parts of chlorinated rubber binder (Parlon, 125 cps. grade), and 40 parts of toluene (solvent) are ground in a pebble mill for 3-4 hours until a smooth dispersion is obtained. The dispersion is spread over the metal surface of a laminate of thin aluminum foil and paper, in a uniform layer and at a thickness of 3 mils (0.003 inch), and the solvent removed by evaporation at moderately elevated temperature. The coated surface is then swabbed with a 5% solution of diphenylamine in ethanol, and dried at room temperature. The thus sensitized sheet is white in appearance and remains substantially unchanged on exposure to normal light although some discoloration takes place on prolonged aging.
The sheet is supported on the flat base of a printing apparatus as described in connection with FIGURE 1 of the drawing, and connection is made between the aluminum foil layer and the paper-holding clamps, which are provided in this case with serrated or saw-tooth edged jaws capable of penetrating the sensitive surface coating to the aluminum foil. A light image through a photographic negative transparency is focused on the paper, which is otherwise in subdued light, and the power supply is turned on. After approximately thirty minutes expo sure, the light-struck areas are found to be deep blue in color. The remainder of the surface remains white or a very faint blue tint.
Example 2 A conductive laminate a employed in Example 1 is coated with a 2-mil thickness of a smooth ball-milled blend of 48 parts by weight of zinc oxide, 4 parts of a resinous copolymer of butadiene and styrene (Pliolite 8-5) as a binder, and 48 parts of toluene as a solvent, and dried. The coated surface is swabbed with a 1% solution of Calcozine Green V dye in ethanol, and again dried. The sheet has a faint green appearance.
The sheet is exposed to a light image formed through a photographic positive transparency while being subjected to corona discharge, as previously descnibed. The sheet is converted to a permanent dark green color at the lightstruck areas.
Example 3 A 2-mil smooth coating of a uniform mixture of 50 parts powdered yellow bismuth trioxide (Bakers CP grade), 5 parts chlorinated rubber, and 4-5 parts toluene is provided on a paper-aluminum foil laminate and dried to produce a pale yellow-colored sensitive copying paper. Exposure for about five minutes under the conditions previously described produces a permanent black image corresponding to the light-struck areas, on the yellow background. Some further darkening of the image occurs on continuing the exposure to fifteen minutes or somewhat longer, and without observable darkening of background areas.
At higher light intensities, the time required for developing the permanent image is substantially reduced, images having been developed within an exposure time of ten seconds without difiiculty. Increased sensitivity, obtained by incorporating trace amounts of lead or cerium in the bismuth oxide pigment, likewise increases the speed of development. One such sensitized composition is 50 parts of Bi O 5 parts of ceric steaiwate, 5 parts of chlorinated rubber (Parlon), and 40 parts of toluene (solvent).
Example 4 The sensitivity of the color change occurring in the sensitive copying paper of Example 3 is increased by applying a thin coating of the bismuth trioxide dispersion over a primary coating of zinc oxide as provided in Example 1.
Example 5 Barium titanate is substituted for the bismuth trioxide in the two-layer coated sheet of Example 4. The copying paper, which is stable on exposure to bright daylight, is converted from an initial white or faint pink color to a black appearance on exposure to light and corona discharge under the conditions described. The image is retained for several days both in the light and in the dark.
Titanium dioxide is equally as effective as the barium titanate in the production of an image on exposure to ion discharge in the presence of a light image, and the resulting image is stable on prolonged storage.
Example 6 The sensitizing coating in this example is formed of a uniform mixture of 50 parts yellow lead oxide, 5 parts chlorinated rubber, and 45 parts toluene, applied to a paper-metal foil laminate at a uniform thickness of 3 mils and dried. Exposure for fifteen minutes produces a mildly black image of the light-struck areas on a yellow background.
Example 7 A conductive backing coated with a thin dried layer of a dispersion of a zinc; cadmium sulfide phosphor powder (in this case, New Jersey Zinc Co.s No. 2220) in a polymeric binder is surface-treated with a variety of dyes to form sensitive copying papers useful in the practice of this invention. Typical dyes are Victoria Green WB, Calcozine Green V and Calcozine Red BX.
While it is not desired to be limited to any theories of operation, it is believed that the following proposed explanation of the surprising results here obtained will aid in arriving at an understanding and appreciation of the principles underlying the invention. The light first activates the photoelectro-sensitive particles, producing in said particles either a decrease or, more commonly, an increase in the conductivity of the particle. The high potential gradient establishes an electrostatic force across the photoelectro-sensitive layer. Any resulting charges at conductive areas of the surface are neutralized by conduction to or from the conductive backing or supporting plate; but such action cannot occur, at least to the same extent, at non-conductive areas, and hence a differential potential pattern, corresponding to the nonlighted areas, is established on the exposed surface. Meanwhile, the corona set up at the high potential source causes ionization of the surrounding air, and particles or ions resulting from such ionization and carrying a suitable charge are drawn toward the oppositely charged areas of the reproduction paper. Chemical action or decomposition of the reactive components within or on the surface of the reproduction paper, resulting in the development of the image, is caused by the presence of reactive atoms, such as oxygen, or the high energy level at the surface of the reproduction, or by the presence of free electrons.
Evidence in support of the above theory in the chemical action is oxidation and is found in the observed fact that the sheet material of Example 1 is inoperable in the photocopying method described when the air normally surrounding the high potential source is replaced by oxygen-free nitrogen. Diphenylamine is converted from light green to dark green by oxidation. It appears likely, therefore, that oxygen ions are responsible for the color change produced in Example 1; and such ions are known to be produced by corona discharge in air. Corona discharge may also produce ions of ozone and of oxides of nitrogen when produced in air, and other ions when produced in other ionizable gases or mixtures of gases. Reactants which undergo a suitable visible change on reaction with such ions are contemplated, therefore, as photodeveloper components for the photoelectro-sensitive coatings of the reproduction papers of this invention.
In the foregoing specific examples, the light image is formed on the sensitive surface by focusing the light passing through a transparent original such as a lantern slide. In analogous manner, the light image may be formed by reflection from an opaque printed surface or from an original article, by methods commonly employed in photography. The light may be filtered through various colored filters for separating colored images into monochromatic components.
As has been previously stated, successful operation of the process depends on the use of a negatively charged electrode of sufliciently high voltage to cause ion discharge toward the copy paper. It has, however, been noted in one instance, i.e. with bismuth trioxide as the photoconductor, that similar reproduction results can be obtained with the electrode positively charged.
Various combinations of irradiation-sensitive materials and dyes may be employed without departing from the scope of this invention. Various other modifications and alterations will become obvious to those skilled in the art from the accompanying disclosure and description.
Having described our invention, we claim:
1. A method for reproduction of a graphic original comprising projecting the graphic original upon a photoconductive copy sheet comprising a metal layer upon which has been bonded thereto a photoconductive layer containing a photoconductor and containing at least one organic compound selected from the group consisting of organic dyes and oxidation-reduction indicators which undergoes a change in color when subjected to a high potential negative ion bombardment to produce a differential conductive pattern comprising relatively non-conductive and relatively conductive areas on the surface thereof corresponding to said graphic original, establishing a high potential gradient between said copy sheet containing said differential conductive pattern and a negative corona electrode in the presence of an ionizable atmosphere, said electrode being positioned from said copy sheet such that the conductive areas of said copy sheet are bombarded with negatively-charged normally gaseous ions, and continuing said bombardment of said copy sheet with said negatively-charged normally gaseous ions for a suflicient length of time to produce a visible reproduction of said graphic original upon the surface of said copy sheet as the result of the color change of the aforesaid organic compound associated with said photoconductive layer.
2. A method for reproduction of a graphic original comprising projecting the graphic original upon a photoconductive copy sheet comprising a metal layer upon which has been bonded thereto a photoconductive layer containing an inorganic photoconductor and at least one organic compound selected from the group consisting of organic dyes and oxidation-reduction indicators which undergoes a change in color upon oxidation when subjected to a high potential oxygen ion bombardment created by a corona discharge to product a differential conductive pattern comprising relatively non-conductive and relatively conductive areas on the surface thereof corresponding to said graphic original, establishing a high potential gradient between said copy sheet containing said differential conductive pattern and a negative corona electrode in the presence of an oxygen-containing atmosphere, said electrode being positioned from said copy sheet such that substantially the entire conductive areas of said copy sheet are bombarded with negativelycharged oxygen ions, and continuing said bombardment of said copy sheet with said negatively-charged oxygen ions for a sufiicient length of time to produce a visible reproduction of said graphic original upon the surface of said copy sheet as the result of the color change of the aforesaid organic compound associated with said photoconductive layer.
3. The method of claim 2 in which said inorganic photoconductor is zinc oxide.
4. The method of claim 2 in which said inorganic photoconductor is cadmium sulfide.
5. The method of claim 2 in which the compound which undergoes a change in color is diphenylamine.
6. The method of claim 2 in which the compound which undergoes a change in color is Calcozine Green V.
7. The method of claim 2 in which the compound which undergoes a change in color is Victoria Green WB.
8. The method of claim 2 in which the compound which undergoes a change in color is Calcozine Red BX.
References Cited by the Examiner UNITED STATES PATENTS 2,692,178 10/1954 Grandadam 961 2,692,948 10/1954 Lion 96-1 NORMAN G. TORCHIN, Primary Examiner,

Claims (1)

1. A METHOD FOR REPRODUCTION OF A GRAPHIC ORIGINAL COMPRISING PROJECTING THE GRAPHIC ORIGINAL UPON A PHOTOCONDUCTIVE COPY SHEET COMPRISING A METAL LAYER UPON WHICH HAS BEEN BONDED THERETO A PHOTOCONDUCTIVE LAYER CONTAINING A PHOTOCONDUCTOR AND CONTAINING AT LEAST ONE ORGANIC COMPOUND SELECTED FROM THE GROUP CONSISTING OF ORGANIC DYES AND OXIDATION-REDUCTION INDICATORS WHICH UNDERGOES A CHANGE IN COLOR WHEN SUBJECTED TO A HIGH POTENTIAL NEGATIVE ION BOMBARDMENT TO PRODUCE A DIFFERENTIAL CONDCTIVE PATTERN COMPRISING RELATIVELY NON-CON DUCTIVE AND RELATIVELY CONDUCTIVE AREAS ON THE SURFACE THEREOF CORRESPONDING TO SAID GRAPHIC ORIGINAL, ESTABLISHING A HIGH POTENTIAL GRADIENT BETWEEN SAID COPY SHEET CONTAINING SAID DIFFERENTIAL CONDUCTIVE PATTERN AND A NEGATIVE CORONA ELECTRODE IN THE PRESENCE OF AN IONIZABLE ATMOSPHERE, SAID ELECTRODE BEING POSITIONED FROM SAID COPY SHEET SUCH THAT THE CONDUCTIVE AREAS OF SAID COPY SHEET ARE BOMBARDED WITH NEGATIVELY-CHARGED NORMALLY GASEOUS IONS, AND CONTINUING SAID BOMBARDMENT OF SAID COPY SHEET WITH SAID NEGATIVELY-CHARGED NORMALLY GASEOUS IONS FOR A SUFFICIENT LENGTH OF TIME TO PRODUCE A VISIBLE REPRODUCTION OF SAID GRAPHIC ORIGINAL UPON THE SURFACE OF SAID COPY SHEET AS THE RESULT OF THE COLOR CHANGE OF THE AFORESAID ORGANIC COMPOUND ASSOCIATED WITH SAID PHOTOCONDUCTIVE LAYER.
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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3329590A (en) * 1961-04-07 1967-07-04 Minnesota Mining & Mfg Electrolytic development of a subtractive color-forming photoconductive member
US3453639A (en) * 1964-04-15 1969-07-01 Itek Corp Electron beam recording on a photoconductive record medium
US3495266A (en) * 1963-09-23 1970-02-10 Minnesota Mining & Mfg Process for forming visible images by electron beam recording
US3653895A (en) * 1970-03-11 1972-04-04 Crown Zellerbach Corp Reproduction utilizing a bichargeable photoconductive layer containing zinc oxide and titanium dioxide
US3658523A (en) * 1968-04-26 1972-04-25 Agfa Gevaert Nv Photoconductive recording member utilizing a mixture of zinc oxide and cadmium sulphide-cadmium selenide
US3946401A (en) * 1973-02-15 1976-03-23 Xerox Corporation Electrothermographic image producing techniques

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2692178A (en) * 1948-04-30 1954-10-19 Onera (Off Nat Aerospatiale) Method and material for graphical registering or direct recording
US2692948A (en) * 1948-12-29 1954-10-26 Kurt S Lion Radiation responsive circuits

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2692178A (en) * 1948-04-30 1954-10-19 Onera (Off Nat Aerospatiale) Method and material for graphical registering or direct recording
US2692948A (en) * 1948-12-29 1954-10-26 Kurt S Lion Radiation responsive circuits

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3329590A (en) * 1961-04-07 1967-07-04 Minnesota Mining & Mfg Electrolytic development of a subtractive color-forming photoconductive member
US3495266A (en) * 1963-09-23 1970-02-10 Minnesota Mining & Mfg Process for forming visible images by electron beam recording
US3453639A (en) * 1964-04-15 1969-07-01 Itek Corp Electron beam recording on a photoconductive record medium
US3658523A (en) * 1968-04-26 1972-04-25 Agfa Gevaert Nv Photoconductive recording member utilizing a mixture of zinc oxide and cadmium sulphide-cadmium selenide
US3653895A (en) * 1970-03-11 1972-04-04 Crown Zellerbach Corp Reproduction utilizing a bichargeable photoconductive layer containing zinc oxide and titanium dioxide
US3946401A (en) * 1973-02-15 1976-03-23 Xerox Corporation Electrothermographic image producing techniques

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