US2180946A - Television transmitting tube - Google Patents

Television transmitting tube Download PDF

Info

Publication number
US2180946A
US2180946A US4024A US402435A US2180946A US 2180946 A US2180946 A US 2180946A US 4024 A US4024 A US 4024A US 402435 A US402435 A US 402435A US 2180946 A US2180946 A US 2180946A
Authority
US
United States
Prior art keywords
electrode
screen
mosaic
tube
electrons
Prior art date
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
Application number
US4024A
Other languages
English (en)
Inventor
George A Morton
Arthur W Vance
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
RCA Corp
Original Assignee
RCA Corp
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Priority to BE413554D priority Critical patent/BE413554A/xx
Application filed by RCA Corp filed Critical RCA Corp
Priority to US4024A priority patent/US2180946A/en
Application granted granted Critical
Publication of US2180946A publication Critical patent/US2180946A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J31/00Cathode ray tubes; Electron beam tubes
    • H01J31/08Cathode ray tubes; Electron beam tubes having a screen on or from which an image or pattern is formed, picked up, converted, or stored
    • H01J31/26Image pick-up tubes having an input of visible light and electric output
    • H01J31/28Image pick-up tubes having an input of visible light and electric output with electron ray scanning the image screen
    • H01J31/30Image pick-up tubes having an input of visible light and electric output with electron ray scanning the image screen having regulation of screen potential at anode potential, e.g. iconoscope
    • H01J31/32Tubes with image amplification section, e.g. image-iconoscope, supericonoscope

Definitions

  • Our invention relates to television transmitting tubes of the type wherein an optical image of an object is translated into an electrical image and the electrical image, in turn, is translated into a 5 train of electrical impulses.
  • our invention relates to transmitting tubes of the type wherein an optical image is utilized to produce an electrical charge or potential image which corresponds, point by point, thereto.
  • an optical image For the purpose of producing the electrical image, heretofore it has been customary to focus the optical image directly upon a screen constituted by a plurality of minute photosensitive metallic globules or particles supported 15 on the surface of an electrode common thereto, the globules being insulated from each other and from the electrode.
  • the photo-electrons emitted by the globules cause each of them to acquire a positive charge 20 with respect to the common electrode or signalplate, each charge being proportional to the intensity and color of that elemental portion of the optical image falling upon the emitting globule.
  • These charges are successively neutralized by a cathode ray to produce a train of electrical impulses, in an output device such as a resistor, representing the optical image.
  • Mosaic screen transmitting tubes of the type referred to above, have great sensitivity.
  • Another object of our invention is to provide a television transmitting tube wherein the phenomenon of secondary emission is made use of for the purpose of intensifying the electrical image.
  • Another object of our invention is to provide a television transmitting tube of the general type under discussion wherein the electrical image is intensified before the scanning operation takes place.
  • a transmitting tube constructed in accordance with our invention includes, within an evacuated envelope, in the order given, a controllable electron source, a, first anode, a second anode, a modified mosaic screen, a reticulated electron-accel- ;5 erating electrode and a planar photosensitive electrode.
  • a controllable electron source a, first anode, a second anode, a modified mosaic screen, a reticulated electron-accel- ;5 erating electrode and a planar photosensitive electrode.
  • an optical image is focused upon the planar electrode thus causingvit to emit.
  • photo-electrons are focused, as a current image, upon the mosaic screen in any convenient way, 5 such as by a magnetic field.
  • the reticulated electrode maintained at a high positive potential with respect to the planar electrodes, accelerates the photo-electrons which, after they pass through the meshes of the screen, strike the globules of the mosaic screen with sufficient velocity to cause secondary emission therefrom.
  • each elemental portion of it impinging upon the minute isolated metal elements'of the mosaic screen, causes the emission of secondary electrons proportionally thereto, thus charging each of the said elements to a positive potential which is alsoproportional.
  • the charge image may be neutralized by a cathode ray which scans the mosaic screen on the side exposed to the primary photo-electrons but this leads to undesired complication in the tube structure. Accordingly, in the preferred 3Q embodiment of our invention under discussion, we cause the cathode ray to scan the opposite side of the screen structure, successively neutralizing discrete charges acquired by the tiny metallic elements thereof, thus producing a train of electrical impulses in an appropriate external output device, such as a resistor, connected to the signal-plate.
  • an appropriate external output device such as a resistor
  • the elements of the mosaic are treated to increase their capability of secondary emission. So 40 far, as a matter of experience, we have found that the secondary emission from photosensitized metallic surfaces is in excess of that from untreated surfaces. For this reason we prefer to photosensitize the surfaces of the globules exposed to the photo-electrons, but it is to be clearly understood that other methods of sensitization may be employed.
  • a tube constructed according to our invention comprises a glass envelope I, having a neck portion 3 in which is mounted an electron source 5, or gun, and a body portion 1 coaxial therewith wherein are disposed in the order given, a mosaic screen structure 9, an electron-permeable reticulated accelerating electrode H and a planar photosensitive electrode I3.
  • the photosensitive electrode I3 is preferably made of silver and the accelerating electrode ll of nickel, molybdenum, tantalum or any other metal which is readily de-gassed and is not easily oxidized.
  • the electron gun includes a cathode thimble I5 on the closed end of which is a layer of electron emissive oxides I1, and which is provided with a heater IS.
  • provided with an opening 23 coaxial with the end of the cathode thimble and closely adjacent tothe layer of electron emitting oxides carried thereby, surrounds the cathode thimble and a cylindrical first anode 25 is supported in alignment therewith.
  • the opposed ends of the cylinders constituting the grid and first anode, respectively, are each telescopically fitted into an encirclingring 21 of insulating material, such as lavite. They are maintained in fixed position by means of tie rods 29 extending between them, the opposed ends of which are fastened. together by beads 3
  • the mosaic screen assembly, the reticulated electrode and the planar photosensitive electrode lie in planes spaced apart along the long axis of the tube and normal thereto.
  • This spacing is maintained by a plurality of tie rods 33, 35, 31 and 39, of nickel or the like, from which leads 4
  • the tie rod 33 is conductively connected to the reticulated electrode
  • the tie rod 35 is connected to the planar photosensitive electrode I3 and has an insulated extension 49 which aids in supporting the reticulated electrode
  • the tie rod 31 is conductively connected tothe signalplate portion of the mosaic screen (hereinafter to be described).
  • the tie rod 39 is shown in the drawings as being provided with an external lead, as it actually appeared in an experimental tube, but this rod has no function other than to contribute to the spacing apart and support of the mosaic screen and the photosensitive electrode.
  • the mosaic screen-assembly 9 is constituted by two discs of mica 5
  • the mosaic screen per se is clamped between these discs and. is held in position by a metallic ring 55 which rests against one disc and is held in contact with the other disc by a plurality of rivets 51.
  • the screen per se, as exemplified by Fig. 4, comprises a section of mesh, or finer, wire screen, the wires 59 of which have been so coated with insulating enamel 6
  • a tiny metallic element or globule 65 Over each of the openings on one side of the screen is disposed a tiny metallic element or globule 65, preferably of silver, having a surface S'l so sensitized as to be capable of high secondary emission.
  • the globules are fused to the insulating
  • the opposite side of the screen may be provided with a metallic coating 69 which surrounds each of the openings and does not obstruct them. This coating, or barrier-grid, is not absolutely essential.
  • the exact method of manufacture of the mosaic screen forms no part of our present invention but it may be made as described in a copending application, in the name of George A. Morton, filed Jan. 30, 1935, Ser. No. 4,023, and assigned to Radio Corporation
  • signal plate is to be understood as meaning the metallic screen per se or both the metallic screen and the metallic coating carried by the insulated screen on the side opposite to the side to which the metallic globules are affixed when such a coating is used.
  • a metallic electrode H in the form of an interior surface coating is carried by the container intermediate the first anode and the mosaic screen assembly.
  • This is a cathode-ray accelerating and focusing electrode and it also functions to remove secondary electrons emitted from the mosaic screen when bombarded by the cathode ray.
  • This electrode hereinafter will be referred to as the second anode.
  • the large electrodes In manufacturing a tube such as has been described, it is, of course, impossible to introduce the large electrodes into it through the neck portion. Accordingly, we have found it expedient to first mount the electron gun in the neck portion, which previously has been given a conductive coating, such as platinum, silver, carbon, etc., to provide the second anode, and thereafter to fuse to it the enlarged portion in which the mosaic screen assembly, the reticulated electrode and the planar photosensitive electrode have been previously positioned. To this end the large portion of the tube may be divided intermediate the reticulated electrode and the photosensitive electrode or at any other convenient point.
  • a conductive coating such as platinum, silver, carbon, etc.
  • the tube is heated and evacuated.
  • oxygen is introduced into the container, at a pressure in the neighborhood of 1 mm. of mercury, for the purpose of oxidizing the surface of the planar electrode and the surface of each of the mosaicglobules opposed thereto.
  • the oxidation of the mosaic globules may be accomplished by causing a glow discharge to take place between them and the reticulated electrode or an exterior, movable electrode.
  • the planar electrode surface may be oxidized by setting up an electrostatic field between it and an exterior terminal of a high potential, high frequency source.
  • both of the electrode surfaces may be oxidized by causing eddy currents to fiow in them, as is customary in de-gassing the electrodes of ordinary thermionic tubes. The oxidation is customarily carried on until the silver surfaces acquire a bluish-green tinge.
  • the container is next baked for about ten minutes at a temperature of 210 Centigrade, which causes the caesium to combine with the silver oxide, giving rise to surfaces which copiously emit secondary elections when bombarded and which are photo-sensitive. During the baking, excess caesium may be pumped out of the container, since it does not adhere to the container wall or to the reticulated electrode and the tie rods.
  • the mica discs included in the mosaic screen assembly make close contact with the inner wall of the container, thus preventing the caesium, in large measure, from leaking past and combining with the second anode.
  • an optical image of an object '53 is focused upon the photosensitive electrode it, which by a suitable source '55, is maintained negative with respect to the second anode ll.
  • the reticulated electrode H by a second suitable source I1, is maintained positive with respect to the second anode H.
  • photo-electrons When an optical image is focused upon the photosensitive electrodes, photo-electrons are emitted. These photo-electrons, constituting a current image, are accelerated toward the reticulated electrode 5 l and, passing through its meshes, fall with high velocity onto the exposed surfaces 57 of the minute silver globules 65 of the mosaic screen, causing the emission of secondary electrons therefrom.
  • a magnetic field symmetrical around the long axis of the tube.
  • Such means may be constituted, as shown in Fig. 5 of the drawings, by a coil l3 surrounding the large portion of the tube intermediate the mosaic screen and the photosensitive electrode, which coil is supplied with direct current from any suitable source 8!.
  • a coil l3 surrounding the large portion of the tube intermediate the mosaic screen and the photosensitive electrode, which coil is supplied with direct current from any suitable source 8!.
  • the photoelectrons in bombarding the exposed portions of the caesiated silver globules drive ofi secondary electrons proportional to the optical image.
  • each small globule acquires a charge in the positive sense with respect to the signal plate constituted by the supporting wire mesh and the metallic coating 69 on the opposite surface thereof, if such coating is present.
  • the signal plate may be connected through a resistor 83and a biasing source 85 to the second anode and also to ground.
  • the biasing source maintains the signal plate a few volts negative with respect to the second anode. If the metallic coating is not present on the screen, the biasing source may be omitted.
  • the first anode in the tube is maintained, by an appropriate source 81', from 200 to 300 volts positive with respect to the cathode and the same source, as shown in the drawings, may be utilized to maintain the second anode at a potential in neighborhood of 1000 volts positive with respect to the cathode.
  • the cathode ray is caused to repeatedly move rapidly over the screen in a horizontal direction and more slowly in a vertical direction in order that it may be caused to successively pass through the openings opposite the small globules and to impinge upon the globules to neutralize the charges thereof and to drive them to equilibrium.
  • the successive neutralization of the charges produced on the globules by secondary emission gives rise to a train of impulses in the resistor 83 connected between the signal plate and ground.
  • This resistor is included in the input circuit of an amplifier tube 93 having an output device, such as a resistor 95, across which amplified potentials corresponding to the train of impulses appear.
  • An optical image is utilized to cause a current image from a photosensitive electrode, the current image is caused to impinge at high velocity upon a mosaic electrode constituted by a plurality of secondary emitters, insulatingly supported on a common signal plate, to thereby drive off secondary electrons.
  • each globule acquires positive charge proportional to the corresponding elemental section of the current image which it receives and these elemental charges are successively neutralized by a cathode ray which is directed toward and falls upon the globules from the side opposite to the side which receives the current image.
  • Successive neutralization of the charges produces a train of electrical impulses, in an output device, which may be suitably amplified by any appropriate means.
  • the electrical image is amplified before the scanning operation.
  • the primary electrical image may be amplified up to ten or more times, giving rise to a device which is many more times more sensitive than analogus devices constructed according to prior art. That is to say, our improved transmitting tube provides a signal of greater amplitude than devices heretofore known, for a given light intensity, thus permitting its use in a television transmitter under conditions which render such older devices entirely inoperative.
  • Apparatus for television and the like including light responsive means for translating an optical image into an electrical current image, means for generating a substantially concentrated beam of electrons, a mosaic electrode positioned between said first named means and said beam generating means, a planar electron permeable mosaic electrode positioned between said first named means and said mosaic electrode, means for applying potential to the mosaic electrode which is positive relative to both the light responsive means and the beam generating means for accelerating the electrons forming the current image in a substantially direct path toward the mosaic whereby the said electrons may be caused to impact one side of the mosaic electrode, means including a secondary emissive layer on said one side of said mosaic electrode for producing secondary electrons in response to bombardment by the electrons of the current image whereby the current image is converted into an intensified electrostatic image, auxiliary means for maintaining the current image in substantially constant spatial focus, means for scanning by the concentrated electron beam that side of the mosaic remote from the secondary electron emisj sive layer to develop therebyla series of picture signals of intensity proportional to the electrostatic charge image existing on the mosaic electrode, and

Landscapes

  • Image-Pickup Tubes, Image-Amplification Tubes, And Storage Tubes (AREA)
US4024A 1935-01-30 1935-01-30 Television transmitting tube Expired - Lifetime US2180946A (en)

Priority Applications (2)

Application Number Priority Date Filing Date Title
BE413554D BE413554A (en)van) 1935-01-30
US4024A US2180946A (en) 1935-01-30 1935-01-30 Television transmitting tube

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US4024A US2180946A (en) 1935-01-30 1935-01-30 Television transmitting tube

Publications (1)

Publication Number Publication Date
US2180946A true US2180946A (en) 1939-11-21

Family

ID=21708759

Family Applications (1)

Application Number Title Priority Date Filing Date
US4024A Expired - Lifetime US2180946A (en) 1935-01-30 1935-01-30 Television transmitting tube

Country Status (2)

Country Link
US (1) US2180946A (en)van)
BE (1) BE413554A (en)van)

Also Published As

Publication number Publication date
BE413554A (en)van)

Similar Documents

Publication Publication Date Title
US2541374A (en) Velocity-selection-type pickup tube
US2433941A (en) Television transmitting tube
US2540621A (en) Electron gun structure
US3073981A (en) Photoconductive pickup tube having an electrically isolated mesh assembly
US2213547A (en) Electron discharge apparatus
US2100259A (en) Television
US2537250A (en) Electronic tube
US3213311A (en) Electron discharge device
US2195489A (en) Television transmitting tube
US2248977A (en) Electro-optical device
US3295010A (en) Image dissector with field mesh near photocathode
US2180946A (en) Television transmitting tube
US2946895A (en) Image tube
US2760096A (en) Television pickup tube
US3474275A (en) Image tube having a gating and focusing electrode
US2324505A (en) Television transmitting tube and electrode structure
US2159568A (en) Picture-translating tube
US2324504A (en) Television transmitting system
US2867687A (en) Cathode ray reproduction tube having auxiliary function of synchronizing signal separation
US3040200A (en) Electron discharge device
US2237896A (en) Electronic device
US3688122A (en) An electrostatic focused electron image device
US2251573A (en) Electronic tube
US2004176A (en) Photo-electric tube
US2163545A (en) Apparatus and method for television transmission