US3317316A - Internal frost recording - Google Patents

Internal frost recording Download PDF

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Publication number
US3317316A
US3317316A US281233A US28123363A US3317316A US 3317316 A US3317316 A US 3317316A US 281233 A US281233 A US 281233A US 28123363 A US28123363 A US 28123363A US 3317316 A US3317316 A US 3317316A
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US
United States
Prior art keywords
layer
frost
insulating
image
deformable
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Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
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US281233A
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English (en)
Inventor
Lloyd F Bean
Robert W Gundlach
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Xerox Corp
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Xerox Corp
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Filing date
Publication date
Application filed by Xerox Corp filed Critical Xerox Corp
Priority to US281233A priority Critical patent/US3317316A/en
Priority to US281181A priority patent/US3321308A/en
Priority to FR973036A priority patent/FR1393821A/fr
Priority to SE5614/64A priority patent/SE319083B/xx
Priority to GB19657/64A priority patent/GB1049903A/en
Priority to GB19656/64A priority patent/GB1069741A/en
Priority to DE1437260A priority patent/DE1437260C3/de
Priority to NL6405291A priority patent/NL6405291A/xx
Priority to FR974708A priority patent/FR1399017A/fr
Priority to BE648043A priority patent/BE648043A/xx
Priority to DE1964R0037911 priority patent/DE1243018B/de
Priority to LU46101D priority patent/LU46101A1/xx
Priority to NO153291A priority patent/NO122729B/no
Priority to CH647764A priority patent/CH469292A/de
Priority to AT436264A priority patent/AT272830B/de
Priority to US616678A priority patent/US3526879A/en
Application granted granted Critical
Publication of US3317316A publication Critical patent/US3317316A/en
Priority to NL7108246A priority patent/NL7108246A/xx
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

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    • 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
    • G03G5/022Layers for surface-deformation imaging, e.g. frost imaging
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G16/00Electrographic processes using deformation of thermoplastic layers; Apparatus therefor
    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G7/00Selection of materials for use in image-receiving members, i.e. for reversal by physical contact; Manufacture thereof
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J31/00Cathode ray tubes; Electron beam tubes
    • H01J31/02Cathode ray tubes; Electron beam tubes having one or more output electrodes which may be impacted selectively by the ray or beam, and onto, from, or over which the ray or beam may be deflected or de-focused
    • H01J31/06Cathode ray tubes; Electron beam tubes having one or more output electrodes which may be impacted selectively by the ray or beam, and onto, from, or over which the ray or beam may be deflected or de-focused with more than two output electrodes, e.g. for multiple switching or counting
    • H01J31/065Cathode ray tubes; Electron beam tubes having one or more output electrodes which may be impacted selectively by the ray or beam, and onto, from, or over which the ray or beam may be deflected or de-focused with more than two output electrodes, e.g. for multiple switching or counting for electrography or electrophotography, for transferring a charge pattern through the faceplate
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N5/00Details of television systems
    • H04N5/76Television signal recording
    • H04N5/80Television signal recording using electrostatic recording
    • H04N5/82Television signal recording using electrostatic recording using deformable thermoplastic recording medium

Definitions

  • Electrostatic deformation recording is a relatively recent art having its origins in the last decade when it was discovered that a latent electrostatic image could produce a fairly high resolution deformation in a low viscosity material. These early deformation processes had severe limitations in that they showed no promise of continuous tone capabilities and were very difiicult to utilize usually requiring complex optical projection systems to convert the deformation pattern into images of contrasting light characteristics.
  • frostable materials are readily adaptable to flexible web or tape structures, it is immedi ately obvious that here might be a suitable medium for image recording on continuous tapes, or reels of tapes where the image may be stored and used at will.
  • frost images are readily erased by heating so that the frostable member becomes reuseable much in the fashion that a magnetic tape is reuseable, after erasure, for new recordings.
  • a major difiiculty has been encountered in the tendency for these materials to pick up dust and foreign matter from the atmosphere deteriorating the performance of the material and producing defects in the images formed.
  • frost material it is necessary to soften the material by heating or solvent action to permit deformation. This softening or heating generally produces a tacky condition which captures and holds lint and other foreign matter so as to prevent any effective cleaning.
  • a tape of frostable material is to be wound on a reel for storage purposes with or without images, it is necessary that the frostable layer be firm and non-tacky while being wound and while being stored so as to prevent frostable material on one part of the tape or web from sticking to the back of the tape on some other part of the web. This means that the materials used for processing must have a high viscosity and a relatively nontacky surface when wound on a reel and while being stored.
  • the material after an image is formed by softening the material, the material must be adequately hardened before winding. This prevents the use of low viscosity ma terials that never completely harden to a dry, non-tacky surface, if they are to be wound and stored on a reel. Likewise, reels cannot be stored under conditions in which the frostable materials can reach a softened state.
  • frostable materials can be made and used in a way such that it is possible to continuously reuse materials without any deterioration in imaging due to foreign matter collecting on the frostable surface. Further in accordance with the present invention, it has been found possible to use materials which tend to remain in a relatively tacky or low viscosity state and to wind the reels while still in such a state and even to store tapes carrying frost images under conditions causing the frostable material to soften and become tacky.
  • FIGURE 1 is a diagrammatic illustration of an embodiment of the invention using corona charging.
  • FIGURES 2, 3, and 4 are diagrammatic illustrations of the embodiments of the invention using conductive electrode charging.
  • FIGURE 5 is a diagrammatic illustration of the embodiment of the invention using selective charging in accordance with a pattern to be reproduced.
  • FIGURE 6 is a diagrammatic illustration of a continuous frost imaging system.
  • FIGURE 7 is a diagrammatic illustration of a frost imaging system using reeled web.
  • FIGURE 8 is a graph showing the relation of projected image density to the refractive index of the frost materials.
  • Frost imaging as disclosed in patent application Ser. No. 193,277, now Patent No. 3,196,001, filed May 8, 1962, is a process in which an outside surface of a thermoplastic layer is selectively subjected to electrostatic stress forces and then softened so that the stressed areas wrinkle to a fine grained light diffusing texture.
  • a similar type of frost image in accordance with the present invention, can be formed at an inside surface more properly denominated an interface. Looking at FIG. 1 for example, a frost image may be formed at the interface of insulating thermoplastic layer 11 and low viscosity.
  • Member 10 further comprises insulating photoconductive layer 13, first supporting layer 15, second supporting layer 16 and conductive layer 17. For reasons that will be discussed, it is preferable that each of these layers be substantially transparent.
  • Supporting layers 15 and 16 can be made of a tough, hard-surfaced electrically insulating material such as glass. Where flexibility is desired, a plastic resin such as polyethylene terephthalate or other polyethylene material or acrylic plastic can be used. Any other insulating transparent material capable of maintaining dimensional stability to temperatures of up to about F. or higher and preferably about 200 F. is suitable. The necessary thermal stability will be determined to some extent by the heat that will be applied to develop or erase the frost image since the requirement is that the supporting plastic layers remain essentially undistorted by such heating.
  • a conductive layer 17 is coated on transparent supporting member 15. This conductive layer must be such as to enable an electrically conductive connection to be made to it.
  • Second supporting layer 16 of the same nature as layer 15 is coated with an insulating transparent photoconductive material.
  • This insulating photoconductive material may suitably be an organic photoconductor such as one of those described in Canadian Patents 568,707 and 611,852 to Neugebauer et'al. and assigned to Kalle & Company. Dip coating, whirl coating, spray coating or other coating process such as described in the said Canadian patents is suitable.
  • the thickness of the photoconductive insulating layers is suitably about 2 to 5 microns and is operable in a range of about one-half micron to 25 microns. In the embodiment of FIG. 1, as will be apparent in discussing the theory of operation below, it is not essential that the photoconductive layer remain insulating when heated. Normally in the dark, and without the application of heat for development or erasure, the photoconductive layer should have a resistivity of 10 ohm. cm. or more, the most critical feature being a virtual absence of lateral conductivity.
  • frostable layer 11 is coated.
  • the frostable layer is suitably a thermoplastic or other readily softenable material that is normally electrically insulating and firm at room temperatures.
  • Suitable materials may be found in the aforementioned U.S. patent application, Ser. No. 193,277. Particularly suitable materials for layer 11 in the embodiment of FIGURE 1 have been found to be Staybelite ester 5 and Staybelite ester 10 available from the Hercules Powder Company and Pliolite (Type S-7) available from Goodyear Tire and Rubber Company.
  • the frostable material should be softenable to the viscosity of about 10 to 10 poises at temperatures between 100 F. and 200 F.
  • the preferred temperature range is determined at the lower limit by the necessity of maintaining stability under storage and readout conditions and at the high end by the desire to use as little heat as possible in the interests of efficiency as well as by the requirement of staying within the thermal range that will produce distortion or other deterioration in the other layers.
  • the frostable layer 11 is coated over the photoconductive layer 13 by a conventional coating procedure as previously described such as dip, whirl, or spray coating.
  • the thickness of this layer in FIGURE 1 should be substantially less than that of the photoconductive layer. Thinner layers generally .give better resolution than thicker layers, but maximum image density starts falling off below about one micron thickness.
  • layer 12 is applied of material that is relatively electrically conductive as compared to the material of photoconductive layer 13 when in the dark and preferably having a resistivity less than 10 ohm-cm. since higher resistivities tend to decrease the exposure speed of the member.
  • Layer 12 should be of low viscosity or at least softenable, by the temperature required to reduce the viscosity of layer 11 to that required for frost, to a viscosity preferably of the same order or lower than that of layer 11 when heated to frost temperature. Suitable materials have been found to be fluids such as water, alcohol, glycerin, sucrose acetate isobutyrate or a nonionic detergent such as Glim available from B. T.
  • Babbitt Inc. of New York city and materials solid at room temperature such as certain solid polyethylene glycols as, for instance, some available from the Carbide and Carbon Chemicals Company under the name Carbowax and soft or readily softenable plastic or petroleum base materials suitable for frostable layer 11 or various waxy materials such as paraffin to which a conductivity agent has been added. While many additives can produce the necessary conductivity, a particularly appropriate one for plastic resin materials that will not reduce the transparencies of the material has been found to be stannic chloride. Insulating liquids may also be used with the addition of conductivity agents. These liquid materials suitably being silicone oil such as DC200 silicone oil (Dow Corning Corp.
  • Another suitable material has been found to be polymerized ethylene imine 50% aqueous solution having molecular weight range of 30,000 to 40,000 available from Chemirad Corporation of East Brunswick, NJ.
  • Embodiment of FIG. 1 is adapted for applications using corona charging and has the particularly desirable characteristic that when the latent electrostatic image is formed, it is trapped on highly insulating surfaces so that electrical conductivity produced in most transparent photoconductive materials by heating is not objectionable and such photoconductive material may be used.
  • the member 10 is placed in the dark and a corona discharge device 18 is used to charge the surface of transparent supporting layer 16 to a voltage of about 100 to 2000 volts.
  • This charging voltage may be either positive or negative, but is illustrated in FIGURE 1 as a positive voltage which is applied with reference to conductive layer 17.
  • conductive layer 17 is suitably electrically connected to ground or to a reference side of the power supply for operating corona discharge device 18.
  • member 10 After charging, member 10 is exposed to a light image of a pattern to be reproduced. For purposes of illustrative simplicity, this is diagrammatically shown as using crosshatching 20 as representative of dark-areas in a projected image.
  • charge device 18 brings the surface of transparent support layer 16 back to a uniform potential. The exposure maybe made through either transparent support layer 16 or through transparent support layer 15 and, if desired, charge may be simultaneous with exposure so that separate charging before and after exposure is not necessary.
  • member 10 After the charging and exposure steps, member 10 is heated until a frost image appears at the interface of frostable layer 11 and relatively conductive layer 12. The temperature required will vary with the amount of electrical charge applied, to the extent of exposure and the thermal characteristics of frostable layer 11.
  • frost threshold The further factor involving the frost threshold is the relative surface tension of the frostable material layer 11 and the relatively conductive material of layer 12, since frost is apparently associated with surface tension eifects. Selection of the material for these two layers to reduce surface tension will likewise reduce the frost threshold so that a frost image may be developed with higher viscosities, lower electrical fields or both. Some interfacial tension is necessary to enable erasure; however, most nonmiscible materials seem to provide adequate tension. For example, surface tension can be reduced considerably by using a material such as Staybelite ester 5 for layer 11 and silicone oil, Dow Corning Type DC 200, for layer 12 with conductivity agents added as .necessary. The heat required to develop a frost image will generally be in the range of 100 F.
  • member 10 is cooled to fix the image and then the image may be observed by light transmitted through the member. It can be observed directly by light passing through the opposite side of the member or with a projection lamp and lenses.
  • the frost image may be focused on a projection screen. Since the transparent supporting layers and 16 preferably have no lightdiffusing characteristics, the light-diffusing image may be viewed from the same side that the member is illuminated from, that is, the side on which all layers are transparent down to the image interface, but such a diffusely reflecting image is relatively inefficient in its use of light. Thus, transmitted light is preferable for projection purposes and, accordingly, it is desirable that all layers of the imaging member be transparent.
  • the corona discharge device When the corona discharge device is first operated under the surface of layer 16, it applies a uniform density of electrostatic charges as indicated by a first row of signs illustrated immediately adjacent to the surface of layer 16.
  • charges of opposite polarity passing through the connection to reference potential are attracted through conductive layer 17 and relatively conductive layer 12 to the interface of the relatively conductive layer 12 and insulating frostable layer 11. These latter charges are indicated by a first row of signs immediately adjacent to the interface of layers 11 and 12.
  • member 11 can be viewed as a capacitor in which the plates are considered to be the surface of layer 16 on one side and relatively conductive layer 12 on the other side with a dielectric between them comprised of layers 11, 13 and 16.
  • the capacity of this capacitor will be determined by the formula K is the dielectric constant of the layers, A is the area of the plates and d is the thickness of the dielectric.
  • K is the dielectric constant of the layers
  • A is the area of the plates
  • d the thickness of the dielectric.
  • the exposed areas of photoconductive layer 13 become relatively conductive, reducing the effective thickness of the dielectric and thus increasing the capacity as is obvious from the above formula.
  • the corona discharge device restores the voltage uniformly to the same level as before and, in doing so, increases the charge density in the illuminated areas shown by a second row of signs above the first row at the surface of layer 16 and by a second row of signs below the first row at the interface of layers 11 and 12.
  • the entire photoconductive layer may become conductive (as long as it remains laterally insulating) without any noticeable loss of image response, since this will only decrease the voltage across the combined member and will not effect the charge distribution. Note that frost development is produced by variations in charge density, unlike xerographic powder development dependent on voltage variations.
  • the relatively conductive layer illustrated as layer 12, FIG. 1 can be eliminated, and a frost image can be formed at the interface between the frostable insulating layer 11 and deformable photoconductive layer. (Thus, in FIG. 1, a slight modification can be made using a deformable photoconductor.
  • the relatively conducting layer 12 may be eliminated and insulating layer 11 may be bonded directly to conductive layer 17.
  • Appropriate photoconductive materials for this purpose can be obtained by mixing transparent organic photoconductive materials, such as those listed in the aforementioned Canadian patents assigned to Kalle & Company, in solutions containing appropriate mixtures of insulating and readily softenable resins such as, for example, polyvinyl chloride and Staybelite in order to give the desired low viscosity on heating and still be highly electrically insulating in the absence of light. Heat and pressure is usually adequate to accomplish bonding between preformed layers.
  • FIG- URE 2 An embodiment of these variations is illustrated in FIG- URE 2.
  • the conductive layer 17 is coated on transparent supporting layer 15 as in FIGURE 1.
  • a deformable photoconductive layer 25' is coated by any conventional technique such as dip coating, whirl coating, or spray coating or, where a layer of elemental photoconductor is used, coating by evaporation.
  • This deformable photoconductive layer can be made of transparent organic photoconductive material mixed with polyvinyl chloride and Staybelite as suggested above.
  • the combination of resins used must be selected so as to avoid excessive loss of resistivity by heating.
  • the resistivity, in the presence of the heating required to develop a frost image and in the absence of light, of the resin-photoconductor material must be 10 ohm-cm. or greater.
  • Insulating deformable layer 11 is coated on the deformable photoconductive layer and support layer 16 precoated with second transparent conductive layer 26 is applied with the conductive side first against the surface of deformable insulating layer 11.
  • a voltage source is connected between conductive layers 26 and 17.
  • the polarity of this connection is not critical; however, some photoconductive layers are more sensitive under a given polarity of applied voltage and, in such cases, the polarity producing the greatest sensitivity is used.
  • the voltage source may appropriately be a pulse generator capable of delivering an electrical pulse for a predetermined interval of time.
  • the member is exposed to a light image of a pattern to be reproduced as for example light reflected from subject 27 through lens system 28 and focused on deformable photoconductive layer 25 of the member.
  • the exposure is made simultaneously with the member being heated to frost temperature by heating device 31 (illustrated in FIGURE 3) which is appropriately an electrical resistance heating element or any other conventional heating source for such purposes and with the voltage pulse application.
  • heating and application of the voltage may be conducted until the frost image is formed or they may be applied for a fixed interval as determined by experimentation.
  • the applied voltage is operable within the range of 350 to 1200 volts, and the necessary heating, as with the other embodiments, should be in the range of 100 F. to 200 F., depending upon the temperature necessary to soften the photoconductive insulating material and the deformable insulating material to a viscosity of about 10 poises such as is necessary to produce frost.
  • FIGURE 2 The operation of the embodiment of FIGURE. 2 is somewhat different from that of FIGURE 1.
  • frost deformation the surface or interface being deformed must be subjected to a build-up of electrical charges immediately at the interface.
  • FIGURE 2 after the application of voltage, no charges appear at the interface of layers 11 and 25 in the dark.
  • layer 25 On illumination to an image pattern, layer 25 becomes relatively conducting in the illuminated areas, and charges migrate to the interface providing the necessary frost conditions in those areas.
  • the heat for development is preferably simultaneous since this will maintain different conductivities and, hence, different charge in the illuminated areas with respect to the non-illuminated areas.
  • the heat for development may be applied before exposure or during exposure as desired as long as the deformable layers are at frost temperature at some time during the exposure and while the member is in a charge condition.
  • Embodiment of FIG. 3 may be fabricated applying a transparent conductive layer such as copper iodide to transparent supporting layer 15 of A mil polyethylene terephthalate for example.
  • the copper iodide or similar material is suitably evaporated on transparent support layer 15.
  • the other surface of transparent support layer 15 is then coated with deformable photoconductive layer 25 substantially identical to layer 25 in FIG. 2.
  • Nonmiscible transparent conductive deformable layer 12 is then coated over photoconductive layer 25.
  • Second transparent supporting layer 16 similar to layer 15 is then coated with transparent conductive layer 26 of the same nature as conductive layer 17.
  • the coated transparent supporting layer 16 is then applied with the coated surface against the surface of deformable conductive layer 12 and bonded by pressure or heat and pressure.
  • the operation and theory of operation in the embodiment of FIGURE 3 is that on application of potential source 27, electrical charges migrate uniformly through layer 12 to the deformable interface. On exposure to a pattern of illumination, the charges in the illuminated areas migrate on through the photoconductor removing the charge from the deformable interface in the illuminated areas. On heating, only the non-illuminated areas frost.
  • FIGURE 4 illustrates an embodiment that is essentially similar to FIGURE 2, except that the need for a deformable photoconductive material has been avoided.
  • nondeformable photoconductive layer 13 similar to layer 13 in FIGURE 1, is utilized.
  • the photoconductive material of layer 13 in FIGURE 4 is slightly more limited than that used in FIGURE 1 since it must remain insulating although heated to frost temperatures. However, it may be readily made as from a solution of an organic photoconductor mixed with polyvinyl chloride or other plastic resin that does not readily exhibit conductivity on heating.
  • Insulating deformable layer 11 is then coated over the photocondutcor as in FIGURE 2, and a relatively conductive thermoplastic layer essentially identical to layer 12 in FIGURE 1 is coated on top of the deformable insulating layer 11.
  • This relatively conductive layer 12 forms a deformable interface with deformable insulating layer 11.
  • a preferred example of the embodiment of FIGURE 4 comprises a 5 microns organic photoconductor for layer 13, 2 /2 microns of Staybelite ester 10 for layer 11, and about 1 micron of fluorocarbon for layer 12 and /2 mil Mylar having evaporated coatings of copper iodide for layers 15 and 16.
  • Layer 13 can be made, for example, by mixing TO 1920 photoconductor available from Kalle & Company and Vinylite VYNS resin available from Carbide and Carbon Chemicals Co., along with Rhodamine B dye and dimethyl ethyl ketone as a solvent. Exemplary proportions are 10 grams TO 1920; 10 grams VYNS; 1 milligram Rhodamine B and 50 milliliters of dimethyl ethyl ketone.
  • This mixture is dip coated over transparent electrode 17 and then baked for three hours at C. This baking process reduces lateral conductivity improving resolution.
  • the Staybelite ester 10 dissolved in Super Naphtholite (American Mineral Spirits Co.) is dip coated over layer 13, and a further baking of one-half hour at 50 C. evaporates the solvent.
  • Layer 12 is then formed by placing on Staybelite layer 11 a small amount of FC 43 fluorocarbon available from Minnesota Mining and Manufacturing Co.
  • Layer 16 carrying transparent electrode 26 is then applied electrode side first against the fluorocarbon which spreads out into a uniform layer.
  • the voltage applied by source 27 should be about 350 to 1200 volts. Dielectric breakdown becomes a hazard over 1000 volts; however, the higher voltages give greater electrostatic contrast and enable the use of harder materials or shorter development.
  • Examples in accordance with the embodiment of FIG- URE 4 have produced resolution greater than 100 lines/mm. with no relief edges.
  • Previous frost images have shown relief edges and frost resolution under 50 lines/ mm. is substantially greater than previously achieved by frost techniques.
  • the resolution improvement is believed attributable to the fact that the image charges in this embodiment are bound in place at a non-deformable interface while the induced charges are at the deformable interface. It does not appear that this configuration allows tangential vectors of electrostatic force at the location of deformation. In prior art frost configurations, the image charges are bound at the deformable surface so that tangential vectors of electrostatic force affect the deformation. This high resolution also applies to the embodiments of FIGURES 1 and 5.
  • FIG- URE 4 The operation and theory of the embodiment of FIG- URE 4 is identical to that of FIGURE 2, except that electrical charges will migrate through relatively conducting layer 12 to the interface of layers 11 and 12 under the potential applied from source 27 and as influenced by the dielectric presented by photoconductive layer 13 and insulating layer 11.
  • the capacitor analogy given in the suggested theory of operation of FIG- URE 1 is applicable.
  • electrical charges can move to the deformable interface through relatively conductive layer 12.
  • the deformable interface receives electrical charges distributed evenly over its entirety.
  • the image density will depend on the relative amount of this additional charge distribution as compared to evenly distributed charge.
  • photoconductive layer 13 preferably occupies a disproportionate amount of the total electrical thickness of the combined dielectric in order to enable a maximum change in capacity on illumination. This is best accomplished by using material of a low dielectric constant (K) for layer 13 and material of a high dielectric constant for layer 11 and in FIGURE 1 for layer 16 also. The physical thickness of the layers is then adjusted so that the equivalent electrical thickness. (-d/K) of the photoconductive layer in the dark is at least as great, and desirably 2 to 3 times greater, than that of layers 11 and 16 combined in FIGURE 1 and layer 11 alone in FIGURE 4.
  • insulating layer 11 have a thickness of /2 to 5 microns, and preferably 2 to 3 microns. Thinner layers give higher resolution, and thicker layers enable greater density.
  • the thickness of the deformable layers is less critical, but it is desirable that at least one of the deformable layers be kept within the range of /2 to 5 microns to provide good resolution.
  • FIGURE 5 illustrates an embodiment in which stencil 29 is positioned over an insulating exterior surface of the member, and corona charging is used to deposit electrostatic charge on the surface in a pattern corresponding to the openings inthe stencil.
  • a member for this purpose may be made in embodiments that are similar to the embodiments of FIG- URES 1-4 with the difference that no photoconductive material is used, and all layers on the side of the deformable interface on which the surface to be selectively charged lies must be highly insulating to avoid shielding effects.
  • FIGURE 5 shows a transparent plastic support layer 15 coated first with a transparent conductive layer 17, secondly with a relatively conductive deformable layer 12.
  • This layer need be only relatively conductive as compared to the usual insulating photoconductive layers in the dark; that is, having less resistance than about ohm-cm. Also, it may be a liquid or a softenable material that is solid at room temperature.
  • a third coating of deformable transparent insulating material 11 is applied over the relatively conductive material, and this material, as with the material in layer 11 in other embodiments, must be highly insulating having resistivities of 10 ohm-cm. or higher even when heated to frost temperatures of 100 F. to 200 F.
  • a fourth coating with transparent insulating material 16 having a non-deformable surface at frost temperatures and similar to support layer 15 is applied.
  • corona discharge device 18 charges insulating support layer 16 through stencil 29 so as to deposit charge on the surface of layer 16 through openings 30.
  • charges of opposite polarity passing through the connection of transparent conductive layer 17 to ground or a reference potential, migrate through the deformable conductive layer 12 to areas at the interface of layers 11 and 12 corresponding to those areas where charge has been deposited on the surface of layer 16.
  • Heating to form a frost image may be simultaneous with charging or can be a separate step after charging. Since the insulating layer 16 will maintain the charge configuration for an extended period of time, development may be delayed for such an extended period.
  • the layer thicknesses are not particularly critical; however, the insulating layer 11 is suitably in the range of A2 to 5 microns for good resolution.
  • the present invention is particularly applicable in com bination with apparatus in which the imaging member is to be continuously recycled or is to be stored for a length of time carrying images on it which may be later erased in order to reuse the frostable material at a later time.
  • Apparatus for continuous recycling is illustrated in FIGURE 6.
  • the frostable member in FIGURE 6 is illustrated in the form of a cylindrical drum 40. While the frostable member for this purpose may be any of those previously described, it is illustrated as similar to that in FIGURE 2 and like numerals indicate like elements of the FIGURE 2 illustration.
  • transparent support member 15 in the apparatus of FIGURE 6 is preferably a rigid glass or transparent plastic member in the form of a cylinder which carries the other layers in accordance with the invention.
  • the cylindrical drum 40 is rotatable by a motor 4l'through a sequence of processing stations in the operation of the apparatus.
  • These operating stations comprise an exposure or recording station 45 illustrated as a projector for projecting an image pattern of light and shadow onto imaging member 40.
  • a development station 48 which is suitably an electrical resistance heating element, an infrared heating element or other convenient form of heat applicator for raising the imaging member to frost temperature.
  • readout station 50 is illustrated as an optical projection system for transmitting light through imaging member 40 and focusing it in image configuration on a screen or on second recording member 51.
  • the readout system illustrated comprises projection lamp 52, reflector or light shield 53, condensing lens 55 and projection lens 56.
  • erasing station 57 follows the readout station.
  • the erasing station suitably comprises heat source 59.
  • Heat source 59 suitably comprises electrical resistance heating elements that do not radiate actinic light.
  • the imaging member is an endless member operating in cyclical fashion as in the embodiment of FIGURE 6, the conductive layers 17 and 26 are preferably connected by a short circuit during erasure. This ensures restoration of the imaging member to an electrically neutral condition. As illustrated in FIGURE 6, this may be accomplished by dividing layer 26 into three segments separated by insulatingdividers 32. (Such insulating dividers in the case of a tin oxide layer are readily provided by etching away a strip of the layer. A subsequently applied plastic layer will fill in any space.)
  • brush contact 42 and brush contact 46 connect potential source 43 across the conductive layers 17 and 26.
  • brush contact 42 is a double contact to enable electrical connection across insulating dividers 32 in layer 26 and to ensure potential application during exposure and development.
  • the erasure station is positioned opposite the center of brush contact 42 to enable maximum separation between the position where potential is applied and the position for the short circuit.
  • the short circuit is applied by brush contact 33 connected to a common reference potential 34 with brush contact 46.
  • the frost image is relatively stable by the time it reaches readout station 50, and the potential applied at that position is not necessarily critical. Due to the segmentation of layer 26, it is necessary to synchronize the drum rotation with the exposure system to avoid straddling a divider 32 with an exposure frame. Synchronization can be by any known device for that purpose as indicated by block 35.
  • the imaging member 40 is rotated by motor 41, so that it passes through exposure station 45 where an image is focused on the imaging member 40 as by a flash exposure system in which the flashes are fast enough to effectively stop the movement of the drum.
  • This exposure permits charge migration in the photoconductive layer in accordance with the imagepattern so that the charge density in layers 17 and 26 also varies in accordance with the image pattern to maintain the potential constant.
  • the imaging member is then heated until a frost image appears at the interface of layers 11 and 12.
  • the frost image passes through readout station 50 where a light from light source 52 passing through imaging member 40 is modulated by the frost image and is focused by projection lens 56 as an image pattern of light and shadow on screen or recording member 51.
  • light source 52 in the readout station can be flashed at a speed adequate to effectively halt the movement of the drum.
  • frost image After the frost image has been utilized at readout station 50, it is erased at erasure station 57 by the simultaneous application of a higher degree of heat than was used for image development and a short circuit between conductive layers 26 and 17. The heat softens the deformable layers while the short circuit permits electrical discharge of the electrostatic image. With the deformable layers softened and discharged, interfacial tension of the deformable materials causes erasure of the frost. In the rotation from the erasing station 57 to the exposure station 45, the deformable layers are cooled and are again ready for a new imaging cycle.
  • FIGURE 7 shows an apparatus in which the same processing stations as in FIGURE 6 are designated by like numerals.
  • a flexible imaging member or web 60 is used, mounted on a supply reel 61 and fed to a storage reel 62, and corona charging is used instead of electrode layers.
  • transparent support layer of flexible member 60 cannot be rigid, but is preferably a flexible plastic material such as polyvinyl chloride, polyethylene terephthalate and polytetrafluoroethylene.
  • This web can be generally of the structure illustrated in FIGURE 1, having one transparent conductive layer connected at reel 61 to electrical reference 63.
  • the imaging member 60 is drawn from supply reel 61 through a charging station 65, exposure station 45, recharging station 66 and developing station 48. After development at station 48, the imaging member 60 is then drawn through a cooling station 67 where heat sinks or refrigerated plates positioned adjacent to the path of travel of the imaging member cool the web and freeze the frost image.
  • the imaging web 60 is wound on storage reel 62, rotated by motor 70 where the web carrying the frost images may be stored for an indefinite period before utilization.
  • the images on this stored web may be readout at any time in a device essentially similar to a movie projector.
  • the web carrying the images may be utilized repeatedly in projecting the same images again and again or, when the particular stored im ges are 110 longer desired, the images may be erased by heating and the web reused in a new imaging process.
  • FIGURE 8 illustrates the difference in refractive index obtained using a series of materials, each forming an interface with Staybelite ester 10.
  • the size of the projection lens opening must be considered, along with refractive index, to determine the projected image density.
  • the smaller the lens opening the greater the density, but the poorer the resolution and light efficiency.
  • a lens opening of less than f8 is considered too small for microphotographic use. Accordingly, referring to FIGURE 8, it will be seen that materials with a refractive index greater than water when used with Staybelite in the invention will operate best with the use of a Schlieren projection system or the like, particularly for microphotography.
  • the imaging member and apparatus of the present invention is of particular value when used in connection with computer readout and facsimile readout systems or in making black-and-white films for television use where a large quantity of imaging material is used, and/or it is desirable to avoid the delay necessary for photographic film processing.
  • the desirability of the present imaging system and material where large quantities of imaging material are required is in the reusable feature which enables repeated reuse of the same material without the expense of replacing it after every use.
  • An integral imaging member for forming a frost image pattern at an interface by deforming said interface into a pattern of random light diffusing irregularities corresponding in density to the variations in an image input supplied thereto comprising:

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Multimedia (AREA)
  • Signal Processing (AREA)
  • Electrophotography Using Other Than Carlson'S Method (AREA)
  • Photoreceptors In Electrophotography (AREA)
  • Printers Or Recording Devices Using Electromagnetic And Radiation Means (AREA)
  • Filling Or Emptying Of Bunkers, Hoppers, And Tanks (AREA)
US281233A 1963-05-17 1963-05-17 Internal frost recording Expired - Lifetime US3317316A (en)

Priority Applications (17)

Application Number Priority Date Filing Date Title
US281233A US3317316A (en) 1963-05-17 1963-05-17 Internal frost recording
US281181A US3321308A (en) 1963-05-17 1963-05-17 Xerographic induction recording
FR973036A FR1393821A (fr) 1963-05-17 1964-04-30 Procédé d'enregistrement xérographique par induction
SE5614/64A SE319083B (en:Method) 1963-05-17 1964-05-06
GB19657/64A GB1049903A (en) 1963-05-17 1964-05-12 Deformation recording using electrostatic images
GB19656/64A GB1069741A (en) 1963-05-17 1964-05-12 Internal frost recording
NL6405291A NL6405291A (en:Method) 1963-05-17 1964-05-13
DE1437260A DE1437260C3 (de) 1963-05-17 1964-05-13 Vorrichtung zur Aufzeichnung von Informationen
FR974708A FR1399017A (fr) 1963-05-17 1964-05-15 élément de formation d'image intérieurement déformable et appareil permettant del'utiliser
BE648043A BE648043A (en:Method) 1963-05-17 1964-05-15
DE1964R0037911 DE1243018B (de) 1963-05-17 1964-05-15 Elektrophotographisches Aufzeichnungsmaterial zur Herstellung von Deformationsbildern
LU46101D LU46101A1 (en:Method) 1963-05-17 1964-05-16
NO153291A NO122729B (en:Method) 1963-05-17 1964-05-16
CH647764A CH469292A (de) 1963-05-17 1964-05-19 Mehrschichtiger Bildträger zur Aufnahme eines Mattbildmusters und Verwendung des Bildträgers
AT436264A AT272830B (de) 1963-05-17 1964-05-19 Mehrschichtiges Aufzeichnungsmaterial für die Bildaufzeichnung durch elektrostatische Deformation
US616678A US3526879A (en) 1963-05-17 1967-02-16 Internal frost recording apparatus using a deformable photoconductor
NL7108246A NL7108246A (en:Method) 1963-05-17 1971-06-16

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
US281233A US3317316A (en) 1963-05-17 1963-05-17 Internal frost recording
US281181A US3321308A (en) 1963-05-17 1963-05-17 Xerographic induction recording
US61667867A 1967-02-16 1967-02-16

Publications (1)

Publication Number Publication Date
US3317316A true US3317316A (en) 1967-05-02

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US281233A Expired - Lifetime US3317316A (en) 1963-05-17 1963-05-17 Internal frost recording
US281181A Expired - Lifetime US3321308A (en) 1963-05-17 1963-05-17 Xerographic induction recording
US616678A Expired - Lifetime US3526879A (en) 1963-05-17 1967-02-16 Internal frost recording apparatus using a deformable photoconductor

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US281181A Expired - Lifetime US3321308A (en) 1963-05-17 1963-05-17 Xerographic induction recording
US616678A Expired - Lifetime US3526879A (en) 1963-05-17 1967-02-16 Internal frost recording apparatus using a deformable photoconductor

Country Status (10)

Country Link
US (3) US3317316A (en:Method)
BE (1) BE648043A (en:Method)
CH (1) CH469292A (en:Method)
DE (1) DE1437260C3 (en:Method)
FR (2) FR1393821A (en:Method)
GB (2) GB1069741A (en:Method)
LU (1) LU46101A1 (en:Method)
NL (2) NL6405291A (en:Method)
NO (1) NO122729B (en:Method)
SE (1) SE319083B (en:Method)

Cited By (7)

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Publication number Priority date Publication date Assignee Title
US3443938A (en) * 1964-05-18 1969-05-13 Xerox Corp Frost imaging employing a deformable electrode
US3550155A (en) * 1968-01-18 1970-12-22 Itt Printer using a solid state semiconductor material as a switch
US3619054A (en) * 1966-08-09 1971-11-09 Xerox Corp Oil film imaging apparatus
US3795009A (en) * 1970-06-17 1974-02-26 Bell & Howell Co Information recording methods, apparatus and media using deformable magnetized materials
US3915700A (en) * 1972-12-22 1975-10-28 Hoechst Ag Photoconductive thermoplastic lamina
US4077803A (en) * 1975-12-01 1978-03-07 Sperry Rand Corporation Low charge-voltage frost recording on a photosensitive thermoplastic medium
US4233380A (en) * 1972-03-17 1980-11-11 Hoechst Aktiengesellschaft Process for shaping a thermoplastic layer

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US3761951A (en) * 1968-02-25 1973-09-25 Canon Kk Electrostatic image forming apparatus
US3897247A (en) * 1970-12-14 1975-07-29 Hoechst Ag Process for selectively deforming a thermoplastic layer
BE793151A (fr) * 1971-12-24 1973-06-21 Kalle Ag Procede pour produire une image en relief
US4051463A (en) * 1976-01-21 1977-09-27 Xerox Corporation Method and apparatus for inverting the polarity of an input image formed on a surface of an image recording device
US4063222A (en) * 1976-01-21 1977-12-13 Xerox Corporation Selective erasure of image recording devices
US4174881A (en) * 1976-03-05 1979-11-20 Rca Corporation Recording a synthetic focused-image hologram on a thermally deformable plastic
JP2862450B2 (ja) * 1992-12-26 1999-03-03 キヤノン株式会社 画像形成装置
GB2521457A (en) * 2013-12-20 2015-06-24 Isis Innovation Charge stabilized dielectric film for electronic devices

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US2896507A (en) * 1952-04-16 1959-07-28 Foerderung Forschung Gmbh Arrangement for amplifying the light intensity of an optically projected image
US3069681A (en) * 1960-03-14 1962-12-18 Itt System for large-area display of two-color information
US3169061A (en) * 1961-05-01 1965-02-09 Rca Corp Electrostatic printing
US3196008A (en) * 1962-05-08 1965-07-20 Xerox Corp Electrophotographic process for formation of frost-like deformation images in mechanically deformable photoconductive layers
US3196013A (en) * 1962-06-07 1965-07-20 Xerox Corp Xerographic induction recording with mechanically deformable image formation in a deformable layer

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US2200741A (en) * 1937-05-01 1940-05-14 Bell Telephone Labor Inc Electrostatic recording and reproducing
FR959035A (en:Method) * 1946-09-23 1950-03-23
US2777745A (en) * 1952-10-04 1957-01-15 Gen Dynamics Corp Electrostatic recording apparatus
US3040124A (en) * 1956-06-25 1962-06-19 Armour Res Found Transducer head system
NL112816C (en:Method) * 1958-02-07
US3008066A (en) * 1958-08-25 1961-11-07 Gen Electric Information storage system
NL273832A (en:Method) * 1961-01-24
DE1252531B (en:Method) * 1961-10-02
US3196012A (en) * 1962-06-07 1965-07-20 Xerox Corp Half-tone xerography with thermoplastic deformation of the image
US3284196A (en) * 1962-10-11 1966-11-08 Ibm Apparatus and method for electric recording

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US2896507A (en) * 1952-04-16 1959-07-28 Foerderung Forschung Gmbh Arrangement for amplifying the light intensity of an optically projected image
US3069681A (en) * 1960-03-14 1962-12-18 Itt System for large-area display of two-color information
US3169061A (en) * 1961-05-01 1965-02-09 Rca Corp Electrostatic printing
US3196008A (en) * 1962-05-08 1965-07-20 Xerox Corp Electrophotographic process for formation of frost-like deformation images in mechanically deformable photoconductive layers
US3196013A (en) * 1962-06-07 1965-07-20 Xerox Corp Xerographic induction recording with mechanically deformable image formation in a deformable layer

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3443938A (en) * 1964-05-18 1969-05-13 Xerox Corp Frost imaging employing a deformable electrode
US3619054A (en) * 1966-08-09 1971-11-09 Xerox Corp Oil film imaging apparatus
US3550155A (en) * 1968-01-18 1970-12-22 Itt Printer using a solid state semiconductor material as a switch
US3795009A (en) * 1970-06-17 1974-02-26 Bell & Howell Co Information recording methods, apparatus and media using deformable magnetized materials
US4233380A (en) * 1972-03-17 1980-11-11 Hoechst Aktiengesellschaft Process for shaping a thermoplastic layer
US3915700A (en) * 1972-12-22 1975-10-28 Hoechst Ag Photoconductive thermoplastic lamina
US4077803A (en) * 1975-12-01 1978-03-07 Sperry Rand Corporation Low charge-voltage frost recording on a photosensitive thermoplastic medium

Also Published As

Publication number Publication date
US3526879A (en) 1970-09-01
FR1399017A (fr) 1965-05-14
DE1437260B2 (de) 1974-01-31
BE648043A (en:Method) 1964-08-31
CH469292A (de) 1969-02-28
FR1393821A (fr) 1965-03-26
GB1069741A (en) 1967-05-24
DE1437260C3 (de) 1974-08-22
DE1437260A1 (de) 1968-10-10
US3321308A (en) 1967-05-23
NO122729B (en:Method) 1971-08-02
NL6405291A (en:Method) 1964-11-18
SE319083B (en:Method) 1969-12-22
GB1049903A (en) 1966-11-30
LU46101A1 (en:Method) 1972-01-01
NL7108246A (en:Method) 1971-09-27

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