US2143214A - Production of images - Google Patents

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US2143214A
US2143214A US12038A US1203835A US2143214A US 2143214 A US2143214 A US 2143214A US 12038 A US12038 A US 12038A US 1203835 A US1203835 A US 1203835A US 2143214 A US2143214 A US 2143214A
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ions
film
plate
grid
screen
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Selenyi Paul
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Egyesuelt Izzolampa es Villamossagi Rt
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Egyesuelt Izzolampa es Villamossagi Rt
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    • 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
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N1/00Scanning, transmission or reproduction of documents or the like, e.g. facsimile transmission; Details thereof
    • H04N1/23Reproducing arrangements
    • H04N1/29Reproducing arrangements involving production of an electrostatic intermediate picture
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S101/00Printing
    • Y10S101/37Printing employing electrostatic force

Definitions

  • 1,818,760 I have described a cathode-ray oscillograph, which has no fluorescent screen, but writes its record on the inner glass wall of the tube by means of a negatively charged pencil" 25 of rays in the shape of a permanent but invisible line drawn with electrical charges, which can be made visible by spraying the outer wall with a suitable powder.
  • this device has important advantages over other in- 30 struments which rely upon the motion of mechanical elements to detect or indicate variations in such conditions as the intensity of light or of an E. M. F. for example.
  • the response of the cathode ray to a change of condition is ins tan- 5 taneous; it has no detectable inertia.
  • gaseous ions themselves, heretofore always considered'detrimental, can be employed as a means for making reproductions or records ot the variations o! a condition.
  • a beam of such ions is relatively easy to produce and a high vacuum is not required.
  • gas pressure above any employed in the cathode ray tube in order to produce a suilicient quantity of 5 these ions. 1 have found that the gas pressure can be varied all the way from about 0.001 mm. 01' mercury to atmospheric pressures or even slightly above. Higher pressures are not as advantageous.
  • the latent image can be developed and fixed by methods very similar to those employed in making the mentioned cathode ray oscillograms.
  • My invention comprises broadly the use of a beam of gaseous ions to detect, indicate or reproduce variations of any condition, the variations of which are or can be translated into changes in E. M. F. or magnetic force.
  • This invention is obviously capable of the most widespread uses which range all the Way from the simple measurement of an electric current to the reproduction of sounds and even to television. 5
  • the apparatus of my invention comprises the various elements necessary-for carrying out the described process.
  • This apparatus always includes a source of gaseous ions, an electrode or plate for attracting a beam of the said ions, an insulating body having advantageously the shape of a sheet, a membrane, or a ribbon, which affords a receiving surface capable of storing the efiects of the ion charges and which is arranged to intersect the path of the beam of ions, and mechanical means for producing relative motion of the beam of ions and of the receiving surface.
  • the apparatus also may include means for transforming the condition to be measured or recorded into corresponding values of E. M. F. or of magnetic force, and for applying the latter to the beam of ions in such manner as to vary its intensity in accordance with variations in the condition.
  • the apparatus in certain of its modifications includes means for controlling the beam of ions, the varying control arrangement being usually operatively connected to this means.
  • Fig. 1 illustrates an apparatus which may be of electrography
  • Fig. 2 shows an electrogram obtained with the ap aratus of Fig. 1;
  • Fig. 3 represents an improved apparatus in which a control electrode or grid is employed
  • Fig. 4 shows an electrogram obtained with the ap aratus of Fig. 3;
  • Fig. 5 shows the diagram of an alternating current vol a e connected in series with a direct current vo tage:
  • Fi 6 illustrates an apparatus suitable for taking sound records. for example, by electrography; Figs. '7 and 8 represent sound electrograms taken with the aid of the apparatus of Fig. 6, while Fig. 9 represents a television receiving appara tus.
  • element 5 is a carbon electrode serving to form an el ctr c arc with another similar electrode: these elect odes being connected in series with the battery 2 and a resistance 3. Opposite the are there is mounted. at a distance of a few mi l meters, a thin insulating sheet 9 of hard rubber. for examp e, having a thickness of say 0.2 to 1 mm. This is mounted on a sheet of metal 5 which forms the plate or electrode which serves to attract a beam of gaseous ions from the arc.
  • the late and insulating sheet which forms the receiving surface are mounted in such manner that they may be moved at various speeds in the direction of the arrow i in front of the arc.
  • the plate 5 is connected to a source 7 of alternating current of which an electrogram is to be taken; the other terminal of the alternating current being connected to one terminal of the battery 2.
  • the electric arc In the operation of the device of Fig. 1, the electric arc generates gaseous ions part of which are negatively and part positively charged.
  • the plate 5 is evidently charged negatively with respect to the electric arc and at this moment the plate attracts positively charged ions which are intercepted by the screen 6 and held on the screen by electrostatic forces; the plate 5 and screen 6 acting as one plate and the dielectric, respectively, of an electric condenser.
  • the plate and screen are moved through a predetermined distance, hence there is producedon the screen a spot of positive ions having a shape resembling the arc .with a width depending upon the rapidity of motion of the plate and screen.
  • the plate is charged positively with respect to the arc and hence a beam of negatively charged ions is attracted to the plate 5.
  • This beam is again intercepted by the screen, the ion charges being held on the screen as before and a spot of negatively charged ions being produced.
  • This latter spot is produced at some distance to one side of the first spot of positively charged ions owing to the motion of the plate and screen. It is thus seen that a latent image is produced on the screen comprising a row or series of spots of ions being charged alternately positively and negatively.
  • the latent image on the screen 6 can be developed by any of the methods used in the development of cathode ray oscillograms mentioned above.
  • the screen may be sprayed by a mixture of nely powdered sulfur and minium, the well-known ele'ctroscopic powder.
  • a record produced as described above can be projected on a screen by a stereopticon without being fixed.
  • the record can, however, be readily fixed by spraying with a transparent binder such as shellac or a nitrocellulose lacquer, for example.
  • a transparent binder such as shellac or a nitrocellulose lacquer, for example.
  • the sulfur and miniu'm, held to the screen only by electrostatic forces, can be removed by wiping; the electrical charges can be dissipated by heating or by other methods and the screen is then ready for further use.
  • element l represents one of two electrodes serving to form an electric arc, these electrodes being connected in series to the battery 2 and resistance 3.
  • the two electrodes are arranged so as to spread out the arc to some extent in front of the screen 6.
  • a diaphragm 8 provided with a narrow slit 9, directly opposite the arc.
  • This slit produces a narrow beam of ions, excluding the rest. It may have a width ranging from a few hundredths to a few tenths of a millimeter. The beam of ions passing through this slit falls on the screen 6 in the form of a line of definite length and width.
  • the record shown in Fig. 4 does not quite represent a true picture or record of the alternating current.
  • the distance between the various bands is of finite width, while it is known that the voltage of the alternating current merely passes through a value of zero.
  • a certain definite voltage 1. e., a certain electrostatic charge
  • the insulating surface i. e., the hard rubber sheet.
  • no powder will adhere. It is possible to obtain a more accurate representation of the alternating current by imposing a bias voltage upon the alternating current.
  • Fig. 5 there is shown a representation of an alternating current of voltage E connected in series with a bias direct current voltage U. If such a system is connected between the plate 5 and the arc of Fig. 3, as at I, and if the value of the bias voltage is correctly chosen a more accurate representation of the alternating current or other variable condition will be obtained.
  • the best record is obtained of an alternating current when the bias voltage exceeds the maximum voltage of the alternating current voltage by an amount just suflicient to attract ions to the plate 5 when the two voltages are in opposite sense.
  • the record will then not completely fade out at any point but the charges produced on the screen will all be of the same sign.
  • the quantity of electroscopic powder retained on the screen at any point indicates the magnitude of the corresponding voltage.
  • An undistorted representation will also be obtained provided a bias voltage greater than that indicated is employed but in this case the ground will be covered throughout by developing powder.
  • bias voltage has another advantage.
  • the voltage between the arc and the plate is low, approaching zero, the speed of the ions in traversing the distance between the arc and the screen cannot be neglected. If the screen is moved rapidly, therefore there is a certain lag before the ions reach the screen and this causes a phase displacement. This is eliminated provided the bias voltage is chosen sufficiently high so that the variation in the speed of the ions becomes negligible.
  • variable condition is imposed in the plate voltage.
  • the device shown in Fig. 3 can be employed to produce the so-called sound tracks used in the motion picture industry by a very simple manipulation.
  • a sound may be received by one of the usual microphones, the electric currents thereby set up being amplified to suitable extent and this source of E. M. F. being applied as plate voltage or as grid voltage to the plate 5 or the diaphragm 8, respectively.
  • this source of E. M. F. being applied as plate voltage or as grid voltage to the plate 5 or the diaphragm 8, respectively.
  • displacing the plate 5 at uniform speed a record similar to that of Fig. 4 would be obtained as a record of a note of constant pitch, for example.
  • variable condition evidences itself in a varying plate voltage it is necessary that this voltage should have a magnitude of at least about 100 volts. If a grid or control electrode, such as the element 8 in Fig. 3 is employed, this voltage may be greatly reduced and a more fiexible and practical control obtained.
  • element 8 When used as a grid control electrode, element 8 is made of metal. It may be a Wire screen or a plate provided with one or more slits.
  • the varying controlling circuit is then connected to this element, the other terminal being usually connected to the source of ions.
  • my device has all the characteristics of the three electrode vacuum tube and can be used in similar manner. Control of the intensity of the beam of ions is effected by means of the electric field set up by the grid.
  • the source of ions acts as the filament or cathode and the plate 5 serves as the plate, as in a vacuum tube.
  • My device operates withthe so-called space-charge current, that is, a current in which electric particles all having the same charge are moving from the source of ions to the plate, provided a bias plate voltage is employed of sufiicient magnitude to always maintain the plate charged with the same sign with respect to the source of ions.
  • space-charge current that is, a current in which electric particles all having the same charge are moving from the source of ions to the plate, provided a bias plate voltage is employed of sufiicient magnitude to always maintain the plate charged with the same sign with respect to the source of ions.
  • a control electrode or grid the amplification factor of my device is very large, that is, a large plate current can be controlled by means of a very low grid voltage.
  • I employed as a source of ions a heated strip of platinum, having the dimensions of 10 by 2 by 0.2 mm., coated with an alkaline earth metal oxide.
  • the grid was a sheet of metal having a thickness of 0.5 mm. and was provided with a slit 5 by 0.5 mm.
  • the screen was a sheet of hard rubber having a thickness of 0.25 mm. mounted on the external surface of a revolving metal cylinder the latter serving as the plate. The distance between the incandescent cathode and the receiving surface was 0.5 mm.
  • Fig. 6 is a diagrammatic representation of an equipment suitable for producing the so-called sound tracks of a sound film or of the so-called film gramaphone.
  • I0 represents the indirectly heated incandescent cathode functioning as a source of ions.
  • This element may be for example a small tube of platinum coated with an alkaline earth oxide.
  • the heater of the cathode is a small wire passing through the platinum tube and insulated therefrom by means of a layer of magnesia for example.
  • the cathode is advantageously arranged at right angles to the motion of the film and parallel to the slit I2 in the grid or control electrode II. For convenience in illustration, however, the cathode of Fig. 6 has been shown perpendicular to the slit.
  • the heater of the cathode is energized by means of the electric circuit including the battery 2 and resistance 3.
  • the slit I2 in the grid II is arranged at right angles to the plane of the drawing and to the motion of the film I3.
  • the film is made of transparent insulating material, such as acetyl cellulose, and is used as a receiving surface, for the sound pictures.
  • the unexposed film is reeled oil the spool I4 at a constant linear speed and is reeled up on the spool I4.
  • the plate voltage is supplied by the battery 5
  • is connected to the incandescent cathode.
  • the reception of the sound in Fig. 6 is effected by the microphone I6, which is fed by current from battery H.
  • the transmitting transformer is represented at I8.
  • the sound current is amplified if necessary by means of the conventional amplifying equipment shown diagrammatically at IS.
  • the amplified voltage is shown connected in series to a biasing potential supplied by the battery 20 and is then connected between the incandescent cathode II] and the grid II. It is, of course, possible to connect the sound voltage between the plate I5 and the grid II.
  • the film passes over the drum I5 in the direction indicated by the arrows and receives upon its surface a deposit of gaseous ions which thereby produce a latent image.
  • This latent image is developed in the chamber 2 I where the film is sprayed by electrically charged powder particles projected by a blast of. air for example.
  • Means for fixing the record is shown at 22 in the form of a spray gun for coating the film with a light film of lacquer for example. The solvent is evaporated from the lacquer prior to reeling up the film. If desired it is of course possible to optically project or to copy the image either before or after fixing and reeling.
  • Fig. 9 an illustrative embodiment of a device suitable for use as a television receiving set has been shown in Fig. 9.
  • a so-called Nipkow disc which is shown at I I, this disc acting to some extent like the grid II of. Fig. 6.
  • the disc is provided with a series of Openings I2, which may be arranged in a spiral or more advantageously, as in the device illustrated, in a circle concentric with the axis of the disc.
  • An endless insulating film I3 is employed in this embodiment, which is moved in the direction indicated by the arrows 28 by the rotation of reels I5 and I5.
  • An endless band 29 is employed as a plate in this case, this band being driven by drums 30 and 30'.
  • the band 29 is made of conducting material, usually of metal, and is mounted to pass in close proximity to the film I3. It is driven at the same speed as the film and in the same direction by suitable means not shown.
  • the receiving antenna is shown at 32.
  • the electrical impulses received are amplified and usually rectified by the device shown diagrammatically at I 9.
  • One terminal of the amplifier is connected through the bias E. M. F. 20 and the metal brush 35 to the metallic Nipkow disc II, while the other terminal is connected to the incandescent cathode III.
  • the latter is heated indirectly by means of the source of current indicated at 25.
  • the plate voltage is supplied by the battery 5
  • Development of the latent images produced upon the film by the beam of ions is accomplished in the device shown diagrammatically at 2
  • the film traveling in the direction of the arrows passes in front of. the cathode I0 and receives on its surface a beam of gaseous ions.
  • the cathode is advantageously arranged transverse of the film, although for convenience of illustration it has been shown in Fig. 9 in a position parallel to the film.
  • the operative length of the cathode corresponds to the distance between two of the perforations I2 of the Nipkow disc.
  • the electric impulses received by the antenna vary the intensity of the beam of ions, these impulses being received by the Nipkow disc which acts in a manner similar to the grid of a three electrode vacuum tube.
  • the rotation of the disc provides transverse motion of the beam of ions across the film to produce a line element of the desired picture while analysis in the direction of. the motion of the film is accomplished by the motion itself.
  • the Nipkow disc and the film are, of course, driven insynchronism with the picture analyzing elements of the transmitting station.
  • Fig. 9 discloses the combination of a wireless picture transmitter of a known kind in combination with an electrographic picture receiver according to the present invention.
  • the film II3 which moves with constant velocity in the direction of the arrow I28, carries the pictures to be transmitted.
  • the film runs from the reel H4 onto the reel H4, being kept moving by the well known toothed cylinders H5, 5', which also keep the film under tension in a plane parallel to the Nipkow disc.
  • This disc which serves for analyzing the pictures into so-called picture points, is formed with a series of holes I I2 arranged concentrically to the centre of the disc.
  • MI is a line-shaped source of light, which may be a strongly lighted slit, an incandescent lamp with a straight-line filament or the like.
  • the longitudinal axis of the source of light extends in parallel to the plane of the film and vertically to the drawing.
  • the lens I42 projects an image of the source of light onto the circle of holes in the Nipkow disc and the light traversing the holes is collected by the lens I43 and concentrated onto the photoelectric cell I44.
  • the current in the circuit governed by this cell which varies according to the intensity of. light at each individual movement, is amplified in the amplifier I45 and utilized in the known transmitting device I46 for modulating the high frequency oscillations.
  • the radio waves modulated in this manner are emitted by the antenna I32 and received by the antenna 32 of the receiver.
  • a transmitted potential corresponding to a dark spot on the picture beingtransmitted produces a voltage at the receiving station which, in conjunction with the bias E. M. F. 20, produces a corresponding intensity of the beam of gaseous ions passing through the corresponding perforation of the Nipkow disc ll.
  • the picture or image which is beingtransmitted is scanned in synchronism with the scanning produced by the Nipkow disc II and the motion of the film l3 at the receiving station of Fig. 9.
  • the latent image produced upon the film thus corresponds to the picture or image which has been transmitted.
  • the latent image is developed in the device shown at 2
  • This developed image can be viewed directly by means of the rotating mirror 40 which is rotated in synchronism with the film, or it can be projected upon a screen by known methods.
  • the image is removed from the film by the device shown at 4
  • the electrostatic charges produced on the film by removal of the electroscopic powder are removed by the heated cathode 24. This means for removing electrostatic charges can be replaced by various other devices such as a fiame oran arc, for example.
  • the film is then ready to receive another latent image.
  • the process thus resembles to some extent that known as the intermediate film process of television, and it can be employed in a similar mannerat a considerable saving in cost both of equipment and operating expense.
  • One particular advantage which the described process has over the intermediate film process, at the receiving station, is that the varying conditions are used directly, applied to the grid, for
  • the device will operate as a. rectifier. It is thus possible in the reception of sound pictures or of television. for example, to omit the detecting tube from the amplifying equipmentand to apply the modulated high frequency potentials directly to the grid. It is also possible to employ a plurality of control electrodes with different potentials applied to each, after the manner of multi-grid tubes. Feed back can also be employed. It is not necessary that the grid be perforated, since the desired effect can be obtained ior example with solid electrodes arranged in parallel to the beam of ions and forming its lateral boundaries.
  • the sensitivity of the electrographic process approaches that of the photographic process.
  • This sensitivity can be increased still further.
  • the grid current usually has a magnitude of about 10 to 10" amps.
  • the cost of operation is almost negligible. It is therefore obvious that the use of electrography has an important advantage over the use of photography in television.
  • Another advantage of electrography over photography is that in the latter process the picture taken becomes visible only after a time lag of at least 20-30 seconds, while the development of an electrogram is completed within the fraction of a second.
  • the plate element employed in electrography does not need to be in actual contact with the insulating receiving surface. It may be spaced therefrom by from about 0.01 to 0.5 mm. On the other hand this plate does not necessarily have to be behind the film. In some cases, for example when a low gas pressure is used, it may be placed in front of the film, in which case perforations are provided for the transmission of the beam of ions.
  • the composition of the plate may be varied widely. It is only necessary to employ a relatively good conductor to produce an equipotential surface. Or the insulating film may be mounted on a band of metal.
  • the plate may also consist of graphite or other conducting particles embedded in the back of the film. Or metal can be sputtered or cathodically dispersed upon the back of the film in such thin layers that the film is semi-transparent or translucent.
  • the electroscopic powder employed in the invention may be of widely different type. Besides the mixture of minium and sulfur mentioned previously it is also possible to employ a variety of other powders, especially if the electrograph consists of particles having charges of the same sign which is always the case when the bias tension is of sufficient magnitude.
  • my method may be employed in an evacuated chamber as well as at atmospheric pressure.
  • One advantage of employing reduced pressure is that it enlarges the range of choice for the source of ions.
  • At lower pressures it is possible to employ the so-called glow discharge as a source of ions or a simple heated cathode may serve.
  • At higher pressures it is possible to employ the so-called silent discharge produced on points of wires, etc. by the tension of a few thousand volts.
  • an ordinary fiame may be used as source of ions.
  • Cathodes of this nature have the advantage that they can be shaped into designs, for example, it is simple to produce a linear source of ions by the use of a small platinum tube coated with an alkaline earth metal oxide.
  • the entire apparatus shown in Fig. 6 and 9 may be surrounded by an evacuated chamber or only certain parts of these equipments. It is possible for example to make the electrograms in a reduced pressure but to develop and project them at atmospheric pressures. To accomplish this it is only necessary to provide long restricted passages through which to pass the film, which passages produce a high resistance to flow of gases into the evacuated space. It is necessary, of course, to provide continuous evacuation of the chamber in which a reduced pressure is maintained.
  • the electrographio process can be used with advantage for printing, 1. e., for the production of positive paper prints of film negatives and also for making photographic enlargements. This can be effected in the way hereinafter described for the transmission of pictures, however in that case the transmitter and the receiver are combined. mechanically into a self-contained unit.
  • Electrography can be employed advantageously in the telegraphing of pictures.
  • the picture to be transmited which may be transparent or non-transparent, is fixed at the sendingstation on a cylindrical surface and scanned over with a point beam of light in the form of a spiral, the light projected through or reflected from saidpicture being caught by a photoelectric cell which thereby generates electric pulsations.
  • the latter are transmitted by wire to the receiving station there to be applied to the grid of a receiving station for the purpose of modulating the intensity of a beam of ions.
  • This beam of ions is received on an insulated surface mounted on a drum which is rotated in synchronism with the corresponding device at the sending station.
  • the electrogram thus produced can then be developed and, if desired, copied by photographic methods.
  • the electrograms can be sprayed with white shellac or a lacquer and the solvent evaporated. It is also possible to imbed the powder particles into the film by pressing with a roller, for example.
  • the receiving surface may be made of low melting material such as parafiin and this may" be heated to the point at which the electroscopic powder sticks to the surface after cooling.
  • the receiving surface may be made of a material, such as acetyl cellulose, capable of softening upon application of a solvent such as acetone, the powdered image being sprayed with this solvent thereby causing the powder to adhere.
  • means for generating a beam of gaseous ions means for generating a beam of gaseous ions, a receiving surface of insulating material intercepting said beam of ions, 9. diaphragm formed with an opening through which said beam can pass towards said receiving surface, means for generating an electric field having lines of force extending through said opening including electrically charged conductive means affecting the travel of said beam of gaseous ions from said first means to said receiving surface, and mechanicalmeans for maintaining the source of said beam and said receiving surface in relative motion.
  • a source of gaseous ions means for producing a beam of said ions, an insulating surface, a conductive diaphragm arranged between said source of gaseous ions and said insulating surface and possessing an opening for the passage of said beam, an electric field having lines of force extending through said opening to a conductive surface adjacent to said insulating surface, means for controlling the intensity of said beam, and mechanical means for maintaining the source of said beam and said receiving surface in relative motion.
  • means for generating a beam of gaseous ions means for applying a varying potential to the control of the intensity ofsaid beam of ions, a diaphragm having an opening for the passage of said beam of ions, electrical means for directing said controlled beam of ions through said opening of the diaphragm against a moving insulating surface, to thereby produce a latent image and means for rendering said latent image visible.
  • gaseous ions means for applying potentials varying in accordance with the variations of said images to said beam for controlling the intensity thereof in a manner corresponding to said potentials, a diaphragm having an opening for the passage of said beam of ions, electrical means for directing said'controlled beam through said opening against a moving insulating screen to produce latent images on said screen and means for rendering visible the latent images.
  • An apparatus comprising in combination, a source of gaseous ions, a conductor adapted, when electrically charged, to attract a beam of said gaseous ions, an insulating receiving surface adjacent said conductor intercepting the beam of ions attracted by said conductor, a second conductor having an opening intermediate said source of ions and said receiving surface adapted, when electrically charged, to control the passage of ions from said source through said opening to said receiving surface, electric connections between said source of ions and said conductors for electrically charging said conductors, and
  • the method of producing images by means of electrostatic charges which comprises pro ducing a beam of gaseous ions, directing the beam towards a conductive surface displaced therefrom, controlling the intensity of said beam in accordance with varying conditions, intercepting the travel of said beam upon a relatively moving support capable of storing the electrostatic charges of the ions of the beam thereupon, and treating the latent images thus produced with an electroscopic powder.
  • the method of producing images by means of electrostatic charges which comprises producing a beam of gaseous ions, directing the beam towards a conductive surface displaced therefrom, controlling the intensity of said beam in accordance with varying conditions, and intercepting the travel of said beam upon a relatively moving support capable of storing the electrostatic charges of the ions of the beam thereupon.
  • the method of producing images by means of electrostatic charges which comprises producing a beam of gaseous ions, directing the beam towards a conductive surface displaced therefrom, confining the extent of said beam with an electrically charged slotted member, controlling the intensity of said beam in accordance with varying conditions, andintercepting the travel of said beam upon a relatively moving support capable of storing the electrostatic charges of the ions of the beam thereupon.
  • the method of producing images by means of electrostatic charges which comprises producing a beam of gaseous ions at a gaseous pressure within the range of about 0.001 mm. of mercury to atmospheric pressure, directing said beam towards a conductive surface displaced therefrom, controlling the intensity of said beam in accordance with varying conditions intercepting the travel of said beam upon an insulating surface, and producing relative motion between said surface and said beam.
  • the method of producing images by means of electrostatic charges which comprises producing a beam of gaseous ions, directing the beam towards a conductive surface displaced therefrom, controlling the intensity of said beam by varying the electrical potential of said conductive surface in accordance with said varying conditions, intercepting the travel of said beam upon an insulating surface, and producing relative movement between said beam and said surface.
  • the method of producing images by means of electrostatic charges which comprises producing a beam of gaseous ions, directing the beam towards a conductive surface displaced therefrom, confining the extent of said beam with an electrically charged slotted member, controlling the intensity of said beam by varying the electric potential of said slotted member in accordance with said varying conditions, and intercepting the travel of said beam upon a relatively moving support capable of storing the electrostatic charges of the ions of the beam thereupon.

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  • Engineering & Computer Science (AREA)
  • Multimedia (AREA)
  • Signal Processing (AREA)
  • Electrostatic Separation (AREA)
  • Printers Or Recording Devices Using Electromagnetic And Radiation Means (AREA)
  • Elimination Of Static Electricity (AREA)
  • Photoreceptors In Electrophotography (AREA)
  • Treatments Of Macromolecular Shaped Articles (AREA)
US12038A 1934-03-22 1935-03-20 Production of images Expired - Lifetime US2143214A (en)

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Cited By (34)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2583546A (en) * 1948-05-12 1952-01-29 Chester F Carlson Electrophotographic recording
US2585846A (en) * 1939-06-01 1952-02-12 Skiatron Electronics And Telev Receiver tube having movable screen with ionic crystal layer for light modulation
US2716048A (en) * 1952-08-14 1955-08-23 Charles J Young Electrostatic facsimile receiver
US2761416A (en) * 1953-01-02 1956-09-04 Battelle Development Corp Development mechanism for electrostatic images
US2769922A (en) * 1952-02-06 1956-11-06 Time Inc Tape reading mechanism
US2777957A (en) * 1950-04-06 1957-01-15 Haloid Co Corona discharge device
US2777745A (en) * 1952-10-04 1957-01-15 Gen Dynamics Corp Electrostatic recording apparatus
US2804708A (en) * 1955-04-06 1957-09-03 Luther G Simjian Apparatus and method for retouching images
US2879395A (en) * 1955-06-08 1959-03-24 Haloid Xerox Inc Charging device
US2883257A (en) * 1953-05-15 1959-04-21 Bell Telephone Labor Inc Electron beam recording
US2884486A (en) * 1952-12-30 1959-04-28 Western Union Telegraph Co Photoconductive facsimile transmitting apparatus
US2894799A (en) * 1956-08-23 1959-07-14 Gen Telephone Lab Inc High speed recorder system
US2919170A (en) * 1952-11-14 1959-12-29 Burroughs Corp Means for electrostatically recording signals
US2956852A (en) * 1952-11-14 1960-10-18 Burroughs Corp Recording by means of electric charges
US2967082A (en) * 1955-05-20 1961-01-03 Burroughs Corp Electrographic plotter
US2986442A (en) * 1956-07-19 1961-05-30 Century Geophysical Corp Electrophotographic oscillograph for observing slow recurrent signals
US3004819A (en) * 1956-04-09 1961-10-17 Univ California Electrostatic recorder
US3013890A (en) * 1958-07-08 1961-12-19 Xerox Corp Process of developing electrostatic images and composition therefor
US3054961A (en) * 1958-07-11 1962-09-18 Ibm Information storage device employing atomic particle bombardment to effect semi-permanent change in target lattice
US3057997A (en) * 1956-05-21 1962-10-09 Edward K Kaprelian Exposure charged electrophotography
US3065355A (en) * 1959-12-24 1962-11-20 Burroughs Corp Marker sensing device
US3068479A (en) * 1958-05-09 1962-12-11 Burroughs Corp Electrographic recording apparatus
US3094429A (en) * 1959-07-31 1963-06-18 Burroughs Corp Method of electrostatic recording with different inkse
US3148600A (en) * 1960-01-13 1964-09-15 Itt Combined plural carrier electrostatic printing and display system
US3195142A (en) * 1958-04-21 1965-07-13 Burroughs Corp Electrographic recording process and apparatus
US3204247A (en) * 1959-12-24 1965-08-31 Burroughs Corp Electrostatic data display
US3218163A (en) * 1961-05-05 1965-11-16 Bunker Ramo Electro-optical image producing method and apparatus
US3220303A (en) * 1962-02-08 1965-11-30 Burroughs Corp Electrostatic printing apparatus
US3272123A (en) * 1964-01-17 1966-09-13 Cleveland Trust Co Method of printing bowling game scores
US3438053A (en) * 1964-07-20 1969-04-08 Burroughs Corp Electrographic print-head having an image-defining multisegmented control electrode
US4057337A (en) * 1976-05-03 1977-11-08 Eastman Kodak Company Compact viewer
US4337303A (en) * 1980-08-11 1982-06-29 Minnesota Mining And Manufacturing Company Transfer, encapsulating, and fixing of toner images
US5208093A (en) * 1991-03-29 1993-05-04 Minnesota Mining And Manufacturing Company Film construction for use in a plain paper copier
US5298309A (en) * 1991-11-05 1994-03-29 Minnesota Mining And Manufacturing Company Film construction for use in a plain paper copier

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2830114A (en) * 1948-05-12 1958-04-08 Battelle Development Corp Vibrating electrode pickup for the transmission of electrostatic recordings
US2826634A (en) * 1951-04-14 1958-03-11 Atkinson Method and means for magnetic reproduction of pictures
BE518007A (fr) * 1952-02-29

Cited By (34)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2585846A (en) * 1939-06-01 1952-02-12 Skiatron Electronics And Telev Receiver tube having movable screen with ionic crystal layer for light modulation
US2583546A (en) * 1948-05-12 1952-01-29 Chester F Carlson Electrophotographic recording
US2777957A (en) * 1950-04-06 1957-01-15 Haloid Co Corona discharge device
US2769922A (en) * 1952-02-06 1956-11-06 Time Inc Tape reading mechanism
US2716048A (en) * 1952-08-14 1955-08-23 Charles J Young Electrostatic facsimile receiver
US2777745A (en) * 1952-10-04 1957-01-15 Gen Dynamics Corp Electrostatic recording apparatus
US2956852A (en) * 1952-11-14 1960-10-18 Burroughs Corp Recording by means of electric charges
US2919170A (en) * 1952-11-14 1959-12-29 Burroughs Corp Means for electrostatically recording signals
US2884486A (en) * 1952-12-30 1959-04-28 Western Union Telegraph Co Photoconductive facsimile transmitting apparatus
US2761416A (en) * 1953-01-02 1956-09-04 Battelle Development Corp Development mechanism for electrostatic images
US2883257A (en) * 1953-05-15 1959-04-21 Bell Telephone Labor Inc Electron beam recording
US2804708A (en) * 1955-04-06 1957-09-03 Luther G Simjian Apparatus and method for retouching images
US2967082A (en) * 1955-05-20 1961-01-03 Burroughs Corp Electrographic plotter
US2879395A (en) * 1955-06-08 1959-03-24 Haloid Xerox Inc Charging device
US3004819A (en) * 1956-04-09 1961-10-17 Univ California Electrostatic recorder
US3057997A (en) * 1956-05-21 1962-10-09 Edward K Kaprelian Exposure charged electrophotography
US2986442A (en) * 1956-07-19 1961-05-30 Century Geophysical Corp Electrophotographic oscillograph for observing slow recurrent signals
US2894799A (en) * 1956-08-23 1959-07-14 Gen Telephone Lab Inc High speed recorder system
US3195142A (en) * 1958-04-21 1965-07-13 Burroughs Corp Electrographic recording process and apparatus
US3068479A (en) * 1958-05-09 1962-12-11 Burroughs Corp Electrographic recording apparatus
US3013890A (en) * 1958-07-08 1961-12-19 Xerox Corp Process of developing electrostatic images and composition therefor
US3054961A (en) * 1958-07-11 1962-09-18 Ibm Information storage device employing atomic particle bombardment to effect semi-permanent change in target lattice
US3094429A (en) * 1959-07-31 1963-06-18 Burroughs Corp Method of electrostatic recording with different inkse
US3204247A (en) * 1959-12-24 1965-08-31 Burroughs Corp Electrostatic data display
US3065355A (en) * 1959-12-24 1962-11-20 Burroughs Corp Marker sensing device
US3148600A (en) * 1960-01-13 1964-09-15 Itt Combined plural carrier electrostatic printing and display system
US3218163A (en) * 1961-05-05 1965-11-16 Bunker Ramo Electro-optical image producing method and apparatus
US3220303A (en) * 1962-02-08 1965-11-30 Burroughs Corp Electrostatic printing apparatus
US3272123A (en) * 1964-01-17 1966-09-13 Cleveland Trust Co Method of printing bowling game scores
US3438053A (en) * 1964-07-20 1969-04-08 Burroughs Corp Electrographic print-head having an image-defining multisegmented control electrode
US4057337A (en) * 1976-05-03 1977-11-08 Eastman Kodak Company Compact viewer
US4337303A (en) * 1980-08-11 1982-06-29 Minnesota Mining And Manufacturing Company Transfer, encapsulating, and fixing of toner images
US5208093A (en) * 1991-03-29 1993-05-04 Minnesota Mining And Manufacturing Company Film construction for use in a plain paper copier
US5298309A (en) * 1991-11-05 1994-03-29 Minnesota Mining And Manufacturing Company Film construction for use in a plain paper copier

Also Published As

Publication number Publication date
GB449824A (en) 1936-07-06
GB456810A (en) 1936-11-16
FR795574A (fr) 1936-03-17
FR47289E (fr) 1937-03-05

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