US2420314A - High-frequency resonator-tube - Google Patents

High-frequency resonator-tube Download PDF

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US2420314A
US2420314A US484648A US48464843A US2420314A US 2420314 A US2420314 A US 2420314A US 484648 A US484648 A US 484648A US 48464843 A US48464843 A US 48464843A US 2420314 A US2420314 A US 2420314A
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resonator
envelope
plates
gaps
grids
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US484648A
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William W Hansen
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Sperry Gyroscope Co Inc
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Sperry Gyroscope Co Inc
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J25/00Transit-time tubes, e.g. klystrons, travelling-wave tubes, magnetrons
    • H01J25/02Tubes with electron stream modulated in velocity or density in a modulator zone and thereafter giving up energy in an inducing zone, the zones being associated with one or more resonators
    • H01J25/06Tubes having only one resonator, without reflection of the electron stream, and in which the modulation produced in the modulator zone is mainly velocity modulation, e.g. Lüdi-Klystron

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  • the present invention relates generally to high frequency electron discharge apparatus having directly attached hollow resonators, and is more particularly related to velocity modulation electron discharge devices of the type disclosed in Varian Patent No. 2,242,275, issued May 20, 1941, and Hansen et al. Patent No, 2,259,699, issued October 20, 1941.
  • the present invention is a continuation-impart of copending Hansen and Ginzton application Serial No. 417,228, filed October 31, 1941.
  • the present invention more specifically relates to modifications of the devices of the above patents wherein the evacuated portion of the discharge device is substantially confined to the electron beam path, and wherein the frequency range of such tube stluctures and resonators is considerably extended.
  • the principal object of the present invention is to provide novel practical embodiments of high frequency tube structures using resonators in which the evacuated portion of the tube is substantially confined to the electron beam path and the resonators are made external to the evacuated portion and are adapted to be at least partially removable.
  • Another object of the invention is to provide improved removable resonators for use with electron beam tubes, such resonators being external to the evacuated envelope of the tube whereby a minimum amount of metal is exposed to the vacuum itself, thus eliminating sources of gases which have previously tended to decrease the life of the tube by impairing its vacuum.
  • Still another object of the present invention is to provide a series of interchangeable removable external resonators for such an electron beam tube, whereby the frequency range over which the device may operate may be extended greatly beyond that provided by tuning devices usually used with such resonators.
  • further object of the invention is to provide an improved cavity resonator, one element of which is removable and replaceable by an element of different size to provide a different resonant frequency.
  • Another object of the invention is to provide a resonator with a removable element, so designed that tuning devices and energy coupling devices may remain attached to the non-removable portion of the apparatus, and may thus be permanently connected to the device while permitting interchangeability of a part of the resonator itself, to permit change in the operating frequency of the device.
  • Fig. 1 shows a perspective View partly in sec tion of one embodiment of my invention
  • Fig. 2 isa transverse cross sectional view of the device of Fig. 1.
  • Fig, 3 shows a longitudinal cross sectional View of a modification of the present invention
  • Fig. 4 is a perspective view of the removable part of the resonator of Fig. 3.
  • the electron tube of Fig, 1 is formed with two substantially parallel plates H and I2 of conducting material, in which are inset respective electron permeable grids I3 and [4, which are shown in the present instance as formed of thin radial strips which are alternately long and short, and thereby provide efiicient interaction with an electron beam projected therethrough. Any suitable form of electron permeable grid or electrode adapted to interchange energy with an electron beam passing therethrough may be used here.
  • Located between plates H and I2 is a conductive cylinder l6 which carries similar grids I7 and I8 in its ends. Cylinder I6 is insulated from plates H and 12 by respective.
  • which are preferably of a material having good ultra high frequency efficiency, such as quartz or high quality ceramic material. Cylinder i6 is supported by being clamped in position between plates H. and L? with insulating ring spacers [9 or 2] at either end.
  • a clamping collar 22 which engages a shoulder 23 on plate I2, is fastened to plate II by means of bolts 24. It will be seen that upon tightening bolts 24 pressure is applied between collar 22 and plate H, which is transmitted to plate [2 and thereby holds cylinder 16 between insulating rings [9 and 2
  • cylinder [6 The interior of cylinder [6 is made part of the evacuated vessel in which the electron beam is projected.
  • suitable gaskets such as the usual lead-wire gaskets 26, are inserted between insulating rings 19, 2
  • Plates l I and I2 eifectively form conductive extensions of grids l3 and [4, respectively, and connect these grids, which are within the evacuated portion of the device, to the exterior non-evacuated portion of the apparatus.
  • the respective ends of cylinder l6 effectively form conductive extensions of grids I! and I8, and connect these grids to the non-evacuated portion of the device at the exterior surface of cylinder l6.
  • Cylinder It can be considered as having two separate functions. The first function is to serve as a portion of the evacuated envelope, and is effected by its inner surface (subject to vacuum pressure).
  • the second function is to connect grids I1 and I8 and form part of the resonator wall, which may be considered to be effected by the outer surface of cylinder l6 (subject to atmospheric pressure), since the high frequency conduction current flow in the resonator of which cylinder It is a part takes place entirely on this outer surface.
  • the innermost portion of cylinder l6 thus serves as part of the evacuated or vacuum envelope, while the outermost portion of cylinder I6 serves a part of the cavity resonator, as will hereafter appear.
  • tubular supports 2'! and 28 Fastened to plates II and I2 by any suitable means, such as Welding or soldering, are respective tubular supports 2'! and 28.
  • Support 21 also forms a part of the evacuated vessel whose boundary is completed by glass or other insulating end bell 29 having an inwardly directed press 3
  • the end bell 29 may be extended and held clamped against plate H, in any suitable manner, maintaining the vacuous condition of the interior of the device.
  • Supporting tube 28 similarly carries a target electrode or detector plate 33 by any suitable convenient means, such as a similar end bell 30.
  • Plate 33 is preferably disposed at an angle to the axis of the device, for reasons which will be later disclosed.
  • a cylindrical shell is supported between plate H and plate l2.
  • this shell is shown as formed of four arcuate sections in order to permit removal without disassembling the tube or impairing its evacuated condition.
  • plate I2 is made with a flexible section l2 of reduced cross-section. This may be constructed by machining down the plate IE, or by suitably fastening a thin plate I2 to the thicker central portion of plate [2. Collar 39 then bears upon the flexible section 12' and provides good electrical contact between plates H and I2 and the cylindrical sections 34, 35, 36 and 31. It will be clear that any number of cylindrical sections may be utilized, but four have been found to be convenient.
  • the size of the resonant chamber may be changed so that the operating range of the device may be appreciably extended.
  • the joints between the arcuate sections 34--31 will have no efiect on the operation of the device, since these joints do not extend across the direction of current flow on the resonator walls, but are parallel to the current flow.
  • the joints between each of the arcuate sections and plates H and 1.2 are more important, but harmful effects are minimized by the good contact provided by the clamping arrangement. Of course, any other desired clamping arrangement could be used.
  • could be permanently sealed to cylinder [6 and plates H and I2, by any suitable insulator-to-metal seal.
  • a sleeve 42 is slidably mounted upon the cylinder l6, and carries a plate or flange 43 which i parallel to wall II.
  • a flexible spring member 44 may be provided having spring contact with cylinder l6.
  • Energy may be abstracted from the apparatus by means of a coupling loop 46 and an output concentric transmission line terminal 41 fixed to cylindrical shell section 34. If desired, this terminal may be located in either plate H Or 12.
  • wire 49 To assure that substantially no oscillatory current flows in wire 49, it is not directly connected to shell 34-31, but is connected to the inner conductor of a quarterwave concentric transmission line section 50, whose outer conductor is connected to shell 36. Since line 50 presents a very high, theoretically infinite, impedance at its open end, any current in wire 49 is further minimized.
  • the electron beam passes successively through the gap be'tween grids 1 3 and 11, through the interior of cylinder It, and through thegap between grids l8 and 1'4.
  • the -beam is velocity modulated by the oscillating field there present, and thereafter becomes grouped upon passage through-the drift space provided by cylinder l6.
  • Grids I! and I8 serve to substantially completely shield the drift space from the oscillating field of the resonator.
  • the beam Upon passing through the second gap between grids f8 and Id, the beam now gives up energy to sustain the oscillating fieldwithin the resonator. In this manner, oscillations may be generated by the device.
  • the electrons thereafter impinge upon the target electrode '33.
  • Electrode 33 may be grounded, if desired, and will then collect all the electrons of the beam. Electrode 33is slanted so “that secondary electrons will not return through grid [4, but will be collected by the wall of "tube 28. Preferably, suitable cooling means, such as cooling coils wound around tube 28, are provided.
  • The'present device may also operate as a superheterodyneconverter.
  • modulated ultra high frequency energy may be fed into the resonator of the device byway of transmission line 41 and loop 4-6.
  • the frequency of'the resonator, (thatiathefrequency at which the device would generate oscillations) is then selected or adjusted to differ from the carrier frequency of the incoming'modulated energy by'just the amount of the desired intermediate frequency.
  • a negative "potential is applied to detector plate 33, as by means of a'suitable source such as battery M9, through an output or load resistor 5
  • a by-pass condenser '52 serves to by-pass high frequency currents around the battery I 49.
  • the potential on detector plate 33 is so chosen that either all or substantially none of the electrons of the beam would be collected thereby in the absence of oscillations in the resonator. Then, when oscillations are supplied to the resonator, by way of the input line 4'l0r by the action of the electron beam,
  • will represent the modulated intermediate frequency and may'be supplied to succeeding intermediate frequency stages for use as desired. If themodulated carrier has the same frequency as the self-oscillatory frequency ofthe device, the device will operate as a homodyne receiver and the modulation of the'incoming wave will appear as a signal voltage across resistor 5
  • the present device overcomes one of the great- "e'st'difiiculties inherent in'the device ofthe pre- 6 views Patent No. -2,259,690. 'In that patent, the central cylindrical conductor, corresponding to cylinder I S was suspended or floated in a vacuum within 'the resonator shell. As a resultgthe heat unavoidably generated in this cylinde by the action of theelectron beam passing'through the grids could not be dissipated readily, and much trouble was experienced with burned out grids. In the present device, however, the outer surface of the cylinder f6 is inthe-non-evacuated portion of t'hedevice and cooling air may be -con-.
  • a portion of the evacuated envelope of the device is formed by a pair of aligned tu- 'bular members '56 and 5-1 which carry respective electron permeable grids '58 and59 in the adjoining ends thereof.
  • Grids 58 and-59 may be of the same typeas the grids shown in Fig. 1,-or of any other suitable type, and are positioned adjacent to "one another to provide a relatively narrow gap therebetween.
  • "I'heevacuated container is maintained-vacuously continuous by means of a suitable insulating ring 6
  • Fixed to tubes 56 and 51 are respective conductingplates or-flanges62 and 63 which are similar in function and purpose to the plates II and i2 of Fig. 1.
  • shell 64 is illustrated as being formed of two semi-cylindrical sections, each being as shown in Fig. 4, and is provided with a plurality of small locating holes 66 which coact with corresponding holes in the plates 62 and '63, through which locating pins 'Sl'may be passed to position shell 64 concentrically surrounding the grids 58, 59 and the electron beam.
  • Shell 64 is then held tightly between plates 62 and 63 by means of suitable clamps illustrated 'at'6'8.
  • the clamping arrangement of 'Fig. 1 may be utilized here, and, conversely, the clamping arrangement of Fig. '3 might be used in Fig. 1, if desired.
  • one of the plates, such as 63 is provided with a section 69 having reduced cross section which willbe relatively flexible and will prevent the transmission of strains due to clamping. It will be seen that this flexible section 69 is similar in function and purpose to the section l2 of Fig. 1.
  • Plates 62 and 63 may be provided with a plurality'of sets of resonator shell locating holes so that shells of'difiering diameters may be interchanged with the same apparatus to provide corresponding differing operating frequency ranges.
  • Fig. 3 shows a type of tunin device for adjusting the resonant frequency of the resonator over a small range.
  • a preferably conductive plug 13 is made adjustably insertable within the resonant cavity, as by means of a suitable threaded arrangement 14 in the wall '62, and will thereby adjust the resonant frequency of the resonator in the manner taught in the above-mentioned Hansen et al. Patent 2,259,690.
  • a similar type of tuning adjustment may be provided in Fig. 1, if desired.
  • this tuning arrangement may be located in a removable wall, but this is less advantageous.
  • Fig. 3 therefore provides a single resonator having reentrant poles formed by tubes 56 and 51 in which the grids 58 and 59 provide a relatively narrow gap for coupling the resonator with an electron beam to be passed therethrough.
  • the particular construction here, as in Fig. 1, permits the use of interchangeable resonator shells to vary the size of the resonator and thereby vary the desired operating frequency of the device accordingly.
  • resonator shell 64 is shown in two separate sections, it will be understood that any suitable number of sections may be supplied as desired. Furthermore, instead of rendering these sections entirely separable, they may be hinged togethe for convenience of assembly and storage. If desired or necessary, cooling fluid may be passed through the resonator to dissipate the heat generated in grids 58 and 59 in a manner similar to that shown in Figs. 1 and 2.
  • Ultra-high-frequency velocity-modulation apparatus comprising a pair of spaced conductive plates having aligned apertures, an electronpermeable grid fixed within each of said apertures, a conductive cylindrical member positioned between and insulated from said plates and axially aligned with said apertures and grids, said cylindrical member supporting an electronpermea'ble grid at each end thereof, whereby a pair of gaps are produced, each gap being defined by a plate grid and a cylinder grid, means vacuously sealin said cylinder to each of said plates and forming part of the evacuated envelope of said apparatus, a plurality of removable conductive members forming a cylindrical shell between and connected to said plates, said shell forming a cavity resonator with said plates, grids and cylindrical member, and means adjacent one of said gaps for protecting an electron beam successively through one of said gaps, the interior of said cylindrical member and the other of said gaps, whereby ultra-high-frequency oscillations may be set up in said resonator.
  • Ultra-high-frequency velocity-modulation apparatus comprising an evacuated envelope, means inside said envelope for projecting an electron beam through the interior of said envelope, two pairs of electron-permeable electrodes positioned in said envelope for interaction with said beam and forming two gaps to be successively traversed by said beam, each of said electrodes having connected conductive portions extending outside said envelope, and cylindrical conductive means connecting one electrode of each of said pairs to an electrode of the other of said pairs and forming a cavity resonator having a pair of gaps defined by said electrodes, whereby oscillations may be set up in said resonator by the action of said beam passing successively through one of said gaps, one of said cylindrical means and the other of said gaps.
  • Ultra-high-frequency velocity-modulation apparatus comprising an evacuated envelope, two pairs of electron-permeable electrodes within said envelope defining a pair of aligned electronpermeable gaps, conductive means exterior to said envelope and connected to all of said electrodes and forming with said two pairs of electrodes a cavity resonator having concentrated electric field portions at said two gaps, and means in said envelope for projecting an electron beam successively through said gaps to set up oscillations within said resonator.
  • said conductive means comprises a conductive shell conmeeting the outer ones of said electrodes and a conductive cylinder connecting the inner ones of said electrodes, said cylinder forming a field-free drift space through which said electron beam passes between said gaps.
  • Ultra-high-frequency velocity-modulation apparatus comprising an evacuated envelope, two pairs of electron-permeable electrodes within said envelope defining a pair of aligned electronpermeable gaps, conductive means exterior to said envelope and connected to all of said electrodes and forming with said two pairs of electrodes a cavity resonator having concentrated electric field portions at said two gaps, said conductive means comprising a conductive plate connected to each of the outer ones of said grids.
  • said conductive means comprises a conductive plate connected to each of the outer ones of said electrodes and a multi-piece cylindrical conducting member removably connected between said plates and forming the outer shell of said resonator, whereby resonators of difiering resonant frequency may be formed by replacing said conducting member by others of different dimensions.
  • Electron discharge apparatus comprising an evacuated envelope, two pairs of electron-permeable electrodes within said envelope defining a pair of aligned electron-permeable gaps, conductive means exterior to said envelope connected conductively to said electrodes and forming velope for projecting an electron beam successive SlVBlY through said gaps, to set, up oscillations within said resonator means.
  • a high; frequency tube. structure comprising an evacuated. insulating; envelope, two pairs of spaced conducting grids within said envelope, meansin said envelope for setting up an electron beamfor traversing said envelope, a non-evacuated; cavity resonator surrounding said envelope, said cavity resonator having interior wall means spaced from the outer walls of said. resonator, said wall means and said outer walls. being connected to said grids to establish a pair of regions between the pairs; of grids adapted to contain alternating electric fields acting upon the electron beam, whereby one of. said fields produces. recurrent. changes in velocity of electron beam and the other of said fields produces an, interchange of energy between the beam and the resonator;
  • Electron-discharge apparatus comprising an enclosing envelope having a tubular portion, means in said envelope for projecting an electron beam through said tubular portion along the axis thereof, a target electrode along the. path of said beam for receiving said beam, and means in, energy-interchangingrelation with said beam comprising-a pair of electrodes having closely spaced apertured portions within said tubular portion defining a. gap to be traversed by said beam, and a removable resonator-.shell-defining means exterior to said envelope and connected to said pair of' electrodes through said envelope.
  • An ultra-high-frequency super-heterodyne converter comprising cavity resonator means for confining an oscillating electromagnetic field having two; separate electric field portions. separated by a field-free space and having a resonant frequency, means coupled to said resonator means for supplying modulated electromagnetic energy to said resonator means having a nominal carrier frequency differing from said resonant frequency by a desired intermediate frequency, means aligned with said resonator means for passing an electron beam successively through one of said electric field portions, said field-free space and the other of said field portions, and means along the-path of said beam for detecting velocity variations, ofsaid electrons: after leaving-said last field portion, whereby a correspondingly modulated intermediate-frequency wave may be derived from saiddetector means.
  • Electron discharge apparatus comprising a tubular evacuated envelope, a pair of electronpermeable grids within said envelope, means in said envelope for projecting an electron beam through said grids, a pair of parallel conducting plates, disposed transversely of said: envelope and connected respectively to said grids, and a cylindrical. shell: surrounding said: envelope and removahly'fastenedbetween said plates and forming a cavity resonatortherewith, whereby the resonant'firequency of, said resonator may be changed y r rlacmc: said shell.
  • a high frequency tube structure comprising an; evacu ted insulating envelope, a pair of spaced grid structures within said envelope, means in said envelope; for; setting up an electron stream for passage through said grid struc-. tures, and a cavity resonator-having a portion remova r surr unding said envelope, said reso-- mater being coupled: to; said grid structures, wherey' S ll-d n el ctroma n ti field Within said r sonator i used t produce an, el ctric field component between said gridstructures actingupon said electron stream.
  • a high frequency tube structure comprisin an evacuated envelope, spaced grids within said envelope, means in said envelope for; setting; up an electron stream for traversing said envelope and said grids, end wall, membersfixed upon the exterior of said envelope on opposite sides of said grids, and removable wall elements insertable-between said end wall members for forming therewith a, cavity resonator adapted to contain: a standing electromagnetic field having an electric; field component between said grids.
  • tuning means is; carried by one of the said fixed end wall members for'efiects ing the tuning of said resonator,
  • a high frequency tube structure comprisingan, evacuated envelope, a pairof grid strufi-i tures within said envelope, means. in said er 1- velope for producing a beam of chargedparticljes, for successively traversing said grid; structures, and a, cavity resonator removably surrounding; said envelope and cbnductively connectedto said; grid structures through the wall of saidenvelope, said cavity resonator being adapted to contain a standing electromagnetic: field forecasting with said beam.
  • Ultra-high-frequency velocity-modulation apparatus comprising a pair of spaced, conduc-v tiveplates having aligned: apertures, a conductive cylindrical; member-positioned between said'plates and axially aligned with said apertures, whereby a pair of gaps are formed, each gap being defined by one, of said; plates and an end of said.
  • said cavity resonator and: means in said apparatus for adjusting the relative effective alternating voltages across said gaps, without variation of' said gaps.
  • Ultra-high-frequency velocity-modulation apparatus comprising, a pair of 'spaced conductive plates, having aligned, apertures, a conductive cylindrical member positioned between said plates and axially aligned with said apertures, whereby a pair of gaps are formed, each gap being defined by one of said plates and an end of said, cylindri: cal member, a cylindrical shell connected to said plates and forming a cavity resonator with said plates and said cylindrical member, means alignedwith said gaps for projecting an electron beam successively through one of said gaps, the interior of said cylindrical member and the other of said gaps, whereby oscillations are produced within said cavity resonator, and means for adjusting the relative effective alternating voltages across said gaps, said adjusting means comprising a conductive sleeve slidably mounted on and contacting said cylindrical member, and a conductive flange carried by said sleeve parallel to one of said plates whereby the electric freldat one of said gaps may be adjusted by adjusting the
  • Ultra-high-frequency velocity-modulationapparatus comp-rising a pair of spaced conductive plates having aligned apertures, aconductive cylinder-like member positioned between said plates axially aligned with said apertures whereby a pair of gaps are produced, each gap being defined by one of said plates and an end of said member, means sealing said cylinder-like member to each of said plates to form part of the evacuated envelope of said apparatus, cylindrical conductive means connected between said plates and forming a cavity resonator with said plates and cylinder-like member, and means in said envelope for projecting an electron beam successively through one of said gaps, the interior of said cylinder-like member and the other of said gaps, whereby ultra-high-frequency oscillations may be set up in said resonator.
  • Apparatus as in claim 19 further including coaxial-transmission-line means having its outer conductor connected to said cylindrical conductive means and its inner conductor connected to said cylinder-like member.
  • Ultra-high-frequency velocity-modulation apparatus comprisin a pair of spaced conductive plates having aligned apertures, a conductive cylindrical member positioned between and spaced from said plates and axially aligned with said apertures whereby a pair of gaps are produced, each gap being defined by one of said plates and an end of said member, conductive means connected between said plates and forming a cavity resonator with said plates and cylindrical member, means aligned with said gaps for projecting an electron beam successively through one of said gaps, the interior of said cylindrical member and the other of said gaps, whereby ultra-high-frequency oscillations may be set up in said resonator, and dissipating means coupled to said cylindrical member for dissipating electric charges accumulated by said cylindrical member said dissipating means comprising a helically wound conductor connected at one end to said cylindrical member and having its other end forming the central conductor of a short-circuited quarterwave concentric transmission line whose outer conductor is connected to said cylindrical means.
  • High frequency tube structure comprising an evacuated envelope, a pair of spaced apertured electrodes within said envelope, a cavity resonator partially removably surrounding said envelope and coupled to said electrodes whereby a standing electromagnetic field within said resonator produces an electric field component between said electrodes, and means in said envelope for passing a stream of charged particles through said electrodes.
  • Electron-discharge apparatus comprising means defining an enclosing vessel, means at one end of said vessel for producing an electron beam, a target electrode at the other end of said vessel, a pair of electrodes between said beam-producing means and said target electrode defining a gap to be traversed by said beam, a second pair of electrodes between said beam-producing means and said target electrode defining a second gap to be traversed by said beam, and a cavity resonator including conductive Wall means exposed to atmospheric pressure outside said vessel electrically connecting one of said first pair of electrodes and one of said second pair of electrodes and further conductive wall means also exposed to said atmospheric pressure electrically connecting the other electrodes of said pairs.
  • Electron discharge apparatus comprising cavity resonator means providing a pair of electron-permeable gaps and adapted to enclose a standing electromagnetic field having electric field portions at said gaps, and with predetermined efiective voltages, means aligned with said gaps for projecting an electron beam successively through said portions, and means in said apparatus for adjusting the relative effective voltages across said gaps.
  • Electron discharge apparatus comprising means defining an enclosing vessel, means at One end of said vessel for producing an electron beam, a target electrode at the other end of said vessel, a pair of electrodes between said beam-producing means and said target electrode defining a gap to be traversed by said beam, a second pair of electrodes between said beam-producing means and said target electrode defining a second gap to be traversed by said beam, and a cavity resonator including a wall outside of said vessel electrically connecting one of said first pair of electrodes and one of said second pair of electrodes and conductive means electrically connecting the other electrodes of said pairs.
  • Electron discharge apparatus comprising means defining an enclosing vessel, means at one end of said vessel for producing an electron beam, a target electrode at the other end of said vessel, a pair of electrodes between said beam-producing means and said target electrode defining a gap to be traversed by said beam, a second pair of electrodes between said beam-producing means and said target electrode defining a second gap to be traversed by said beam, and a cavity resonator outside of said vessel including means electrically connecting one of said first pair of electrodes and one of said second pair of elec trodes and further including conductive means electrically connecting the other electrodes of said pairs.
  • High frequency tube structure comprising an evacuated envelope, a source of electrons within said envelope, a pair of apertured electrodes within said envelope in alignment with said source, and a further electrode in alignment with said apertured electrodes on the side thereof opposite said source, said apertured electrodes having portions extending to the exterior of said envelope and adapted to be connected to a cavity resonator whereby the electromagnetic field within said cavity resonator may produce an alternating electric field between said apertured electrodes for interaction with said electrons.
  • Electron discharge apparatus comprising means including a source of electrons for producing a stream of electrons along a predetermined path, a pair of electron-permeable electrodes mounted along said path in alignment with said source and defining a narrow gap therebetween, a pair of concentric conductive means connected respectively to said electrodes and defining therewith cavity resonator means adapted to contain a standing electromagnetic field oscillating therewithin, and means in said apparatus for adjusting the effective voltage produced by said field across said gap, said last-named means comprising a fiange member adjustably support- 13 ed on the inner of said conductive means and slidable toward and away from said gap for correspondingly adjusting said effective voltage.

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y 1947- w. w. HANSEN HIGH-FREQUENCY RESONATOR-TUBE 2 Sheets-Sheet 1 Filed April 26, 1945 M y 1947- w. w. HANSEN HIGH-FREQUENCY RESONATOR-TUBE Filed April 26, 1943 2 Sheets-Sheet 2 FIG. 3.
INVENTOR WILLIAM w- HANSEN ATTORNEY Patented May 13, 1947 HIGH-FREQUENCY RESONATOR-TUBE William W. Hansen, Garden City, N. Y., assignfor to Sperry Gyroscope Company, Inc., a corporation of New York Application April 26, 1943, Serial No. 484,648
W 30 Claims.
The present invention relates generally to high frequency electron discharge apparatus having directly attached hollow resonators, and is more particularly related to velocity modulation electron discharge devices of the type disclosed in Varian Patent No. 2,242,275, issued May 20, 1941, and Hansen et al. Patent No, 2,259,699, issued October 20, 1941. The present invention is a continuation-impart of copending Hansen and Ginzton application Serial No. 417,228, filed October 31, 1941.
The present invention more specifically relates to modifications of the devices of the above patents wherein the evacuated portion of the discharge device is substantially confined to the electron beam path, and wherein the frequency range of such tube stluctures and resonators is considerably extended.
The principal object of the present invention is to provide novel practical embodiments of high frequency tube structures using resonators in which the evacuated portion of the tube is substantially confined to the electron beam path and the resonators are made external to the evacuated portion and are adapted to be at least partially removable.
Another object of the invention is to provide improved removable resonators for use with electron beam tubes, such resonators being external to the evacuated envelope of the tube whereby a minimum amount of metal is exposed to the vacuum itself, thus eliminating sources of gases which have previously tended to decrease the life of the tube by impairing its vacuum.
Still another object of the present invention is to provide a series of interchangeable removable external resonators for such an electron beam tube, whereby the frequency range over which the device may operate may be extended greatly beyond that provided by tuning devices usually used with such resonators.
further object of the invention is to provide an improved cavity resonator, one element of which is removable and replaceable by an element of different size to provide a different resonant frequency.
Another object of the invention is to provide a resonator with a removable element, so designed that tuning devices and energy coupling devices may remain attached to the non-removable portion of the apparatus, and may thus be permanently connected to the device while permitting interchangeability of a part of the resonator itself, to permit change in the operating frequency of the device.
provide improved ultra high frequency electrondischarge tube structure adapted to efficiently and conveniently operate as an ultra high frequency oscillator or receiver.
Other objects and advantages will become apparent from the specification taken in connection with the accompanying drawings wherein the'invention is embodied in concrete form.
In the drawings,
Fig. 1 shows a perspective View partly in sec tion of one embodiment of my invention,
Fig. 2 isa transverse cross sectional view of the device of Fig. 1.
Fig, 3 shows a longitudinal cross sectional View of a modification of the present invention, and
Fig. 4 is a perspective view of the removable part of the resonator of Fig. 3.
The electron tube of Fig, 1 is formed with two substantially parallel plates H and I2 of conducting material, in which are inset respective electron permeable grids I3 and [4, which are shown in the present instance as formed of thin radial strips which are alternately long and short, and thereby provide efiicient interaction with an electron beam projected therethrough. Any suitable form of electron permeable grid or electrode adapted to interchange energy with an electron beam passing therethrough may be used here. Located between plates H and I2 is a conductive cylinder l6 which carries similar grids I7 and I8 in its ends. Cylinder I6 is insulated from plates H and 12 by respective. insulating rings I9 and 2|, which are preferably of a material having good ultra high frequency efficiency, such as quartz or high quality ceramic material. Cylinder i6 is supported by being clamped in position between plates H. and L? with insulating ring spacers [9 or 2] at either end. For this .purpose, a clamping collar 22, which engages a shoulder 23 on plate I2, is fastened to plate II by means of bolts 24. It will be seen that upon tightening bolts 24 pressure is applied between collar 22 and plate H, which is transmitted to plate [2 and thereby holds cylinder 16 between insulating rings [9 and 2|.
The interior of cylinder [6 is made part of the evacuated vessel in which the electron beam is projected. For this purpose, suitable gaskets, such as the usual lead-wire gaskets 26, are inserted between insulating rings 19, 2| and plates II, It. and cylinder 16. Then, upon tightening bolts 24, not only is cylinder l6 supported in place, but alsoa vacuum-tight seal. is provided.
3 If desired, ordinary ceramic-to-metal seals could be used here.
Plates l I and I2 eifectively form conductive extensions of grids l3 and [4, respectively, and connect these grids, which are within the evacuated portion of the device, to the exterior non-evacuated portion of the apparatus. Similarly, the respective ends of cylinder l6 effectively form conductive extensions of grids I! and I8, and connect these grids to the non-evacuated portion of the device at the exterior surface of cylinder l6. Cylinder It can be considered as having two separate functions. The first function is to serve as a portion of the evacuated envelope, and is effected by its inner surface (subject to vacuum pressure). The second function is to connect grids I1 and I8 and form part of the resonator wall, which may be considered to be effected by the outer surface of cylinder l6 (subject to atmospheric pressure), since the high frequency conduction current flow in the resonator of which cylinder It is a part takes place entirely on this outer surface.
The innermost portion of cylinder l6 thus serves as part of the evacuated or vacuum envelope, while the outermost portion of cylinder I6 serves a part of the cavity resonator, as will hereafter appear.
Fastened to plates II and I2 by any suitable means, such as Welding or soldering, are respective tubular supports 2'! and 28. Support 21 also forms a part of the evacuated vessel whose boundary is completed by glass or other insulating end bell 29 having an inwardly directed press 3| supporting a cathode 32, as is indicated somewhat schematically in the figure. Instead of having the tubular support 21 affixed to plate H, with the end bell 29 sealed thereto, the end bell 29 may be extended and held clamped against plate H, in any suitable manner, maintaining the vacuous condition of the interior of the device.
Supporting tube 28 similarly carries a target electrode or detector plate 33 by any suitable convenient means, such as a similar end bell 30. Plate 33 is preferably disposed at an angle to the axis of the device, for reasons which will be later disclosed.
In order to complete the resonant circuit or cavity resonator used with the present device,
a cylindrical shell is supported between plate H and plate l2. In the present instance this shell is shown as formed of four arcuate sections in order to permit removal without disassembling the tube or impairing its evacuated condition.
These sections 34, 35, 3B and 31, when placed together, form a complete cylindrical shell which is held clamped between plate H and plate 12 by means of suitable clamping bolts 38 extending between a collar 39 bearing on plate [2 and plate II. In order that clamping and unclamping of the cylindrical shells 34 to 31 will have no effect upon the support or sealing of cylinder 16, plate I2 is made with a flexible section l2 of reduced cross-section. This may be constructed by machining down the plate IE, or by suitably fastening a thin plate I2 to the thicker central portion of plate [2. Collar 39 then bears upon the flexible section 12' and provides good electrical contact between plates H and I2 and the cylindrical sections 34, 35, 36 and 31. It will be clear that any number of cylindrical sections may be utilized, but four have been found to be convenient.
Itwill be seen that by supplying a plurality of sets of these sections 34 to 31, having different diameters, the size of the resonant chamber may be changed so that the operating range of the device may be appreciably extended. Also, the joints between the arcuate sections 34--31 will have no efiect on the operation of the device, since these joints do not extend across the direction of current flow on the resonator walls, but are parallel to the current flow. The joints between each of the arcuate sections and plates H and 1.2 are more important, but harmful effects are minimized by the good contact provided by the clamping arrangement. Of course, any other desired clamping arrangement could be used. Also, if desired, insulating rings I9 and 2| could be permanently sealed to cylinder [6 and plates H and I2, by any suitable insulator-to-metal seal.
The device thus far described will, therefore, operate essentially in the same manner as described in Patent No. 2,259,690, and by suitable choice of the accelerating voltage applied to the electron beam by means of a suitable potential source, such as indicated by battery 4|, oscillations may be set up within the resonant chamber. As discussed in this patent, for best operation the effective voltage appearing across grids l3 and I? should be less than that appearing across grids i8 and M. This may be accomplished by suitably selecting the relative spacing lengths of the gaps between these pairs of grids. By the present invention, however, the relative voltages between the two pairs of grids may be adjusted so that the optimum value can be suitably selected without changing the grid spacing.
For this purpose, a sleeve 42 is slidably mounted upon the cylinder l6, and carries a plate or flange 43 which i parallel to wall II. To assure good electrical contact between cylinder [6 and flange 43, and to hold sleeve 42 fixed once it is adjusted, a flexible spring member 44 may be provided having spring contact with cylinder l6. By adjusting the position of flange 43 before the outer cylindrical shell is put in place, the relative capacitances and hence the efiective voltages at the respective gaps may be suitably adjusted to the proper value.
Energy may be abstracted from the apparatus by means of a coupling loop 46 and an output concentric transmission line terminal 41 fixed to cylindrical shell section 34. If desired, this terminal may be located in either plate H Or 12.
It has been discovered that during operation the electron beam passing through grids ll, 53 and cylinder l6 tends to charge up this cylinder and thereby create harmful effects upon the operation of the device. To prevent this, a direct conductive connection for dissipating static charges is provided between flange 43 and the casing of the device by means of a coiled wire 49. By coiling this wire. 49, it remains a relatively high impedance at the ultra high frequencies involved, and, therefore, has little effect upon the field distribution within the resonator. Furthermore, wire 49 is located at or near the voltage node in the oscillating electromagnetic field within the resonator, so that its effect upon the field is further minimized. To assure that substantially no oscillatory current flows in wire 49, it is not directly connected to shell 34-31, but is connected to the inner conductor of a quarterwave concentric transmission line section 50, whose outer conductor is connected to shell 36. Since line 50 presents a very high, theoretically infinite, impedance at its open end, any current in wire 49 is further minimized.
In operation, the electron beam passes successively through the gap be'tween grids 1 3 and 11, through the interior of cylinder It, and through thegap between grids l8 and 1'4. During its passage through the first gap, the -beam is velocity modulated by the oscillating field there present, and thereafter becomes grouped upon passage through-the drift space provided by cylinder l6. Grids I! and I8 serve to substantially completely shield the drift space from the oscillating field of the resonator. Upon passing through the second gap between grids f8 and Id, the beam now gives up energy to sustain the oscillating fieldwithin the resonator. In this manner, oscillations may be generated by the device. The electrons thereafter impinge upon the target electrode '33. This electrode may be grounded, if desired, and will then collect all the electrons of the beam. Electrode 33is slanted so "that secondary electrons will not return through grid [4, but will be collected by the wall of "tube 28. Preferably, suitable cooling means, such as cooling coils wound around tube 28, are provided.
.The'present device may also operate as a superheterodyneconverter. Thus, modulated ultra high frequency energy may be fed into the resonator of the device byway of transmission line 41 and loop 4-6. The frequency of'the resonator, (thatiathefrequency at which the device would generate oscillations) is then selected or adjusted to differ from the carrier frequency of the incoming'modulated energy by'just the amount of the desired intermediate frequency. Then a negative "potential is applied to detector plate 33, as by means of a'suitable source such as battery M9, through an output or load resistor 5|. A by-pass condenser '52 serves to by-pass high frequency currents around the battery I 49. The potential on detector plate 33 is so chosen that either all or substantially none of the electrons of the beam would be collected thereby in the absence of oscillations in the resonator. Then, when oscillations are supplied to the resonator, by way of the input line 4'l0r by the action of the electron beam,
the electrons leaving grid [4 will have higher and.
lower velocities than the velocity of the beam withoutoscillations in the resonator. If the detector 33 is biased'to jus'tcollect all the electrons of average velocity, those of lowervelocity will be repelled so that the current passing through resistor 5| will vary in accordance with the velocity of'the electrons and'therefore will vary in accordance with' the field in the resonator. When the voltage on detector plate 33 is adjusted to just repel all average Velocity electrons, then faster electrons producedby the velocity modulation in the device will be collected, while slower electrons will not. This also will serve to vary the current through resistor 5| in accordance with the variation in electron velocity.
When the modulated carrier has a frequency difiering' from the self-oscillatory frequency of the device, the voltage appearing across resistor 5| will represent the modulated intermediate frequency and may'be supplied to succeeding intermediate frequency stages for use as desired. If themodulated carrier has the same frequency as the self-oscillatory frequency ofthe device, the device will operate as a homodyne receiver and the modulation of the'incoming wave will appear as a signal voltage across resistor 5| and may be utilized as desired.
"The present device overcomes one of the great- "e'st'difiiculties inherent in'the device ofthe pre- 6 views Patent No. -2,259,690. 'In that patent, the central cylindrical conductor, corresponding to cylinder I S was suspended or floated in a vacuum within 'the resonator shell. As a resultgthe heat unavoidably generated in this cylinde by the action of theelectron beam passing'through the grids could not be dissipated readily, and much trouble was experienced with burned out grids. In the present device, however, the outer surface of the cylinder f6 is inthe-non-evacuated portion of t'hedevice and cooling air may be -con-.
ducted over it for cooling purposes. This may be-done in the present device by connecting one of the tubes-'53 communicating with the interior of the cylindrical shells 3437 -to a suitable source of cooling fluidsu'ch as an air hose.
Some of the features of the present invention can also be applied to regular Klystron tubes, such as of the type described in the above-mentioned 'Varian Patent 2fi242j27'5 orin V-ar ian =PatentNo. 2,250,511. -A portion of such a device is shown in FigsJ-3 and-4. These figures merely illustrate-the construction of one resonator for such a tube, it being understood that such a tube will normally utilize two such resonators in cascade, andthat suitable means for projecting an electron beam-successfullythrough the grids of these resonatorsand for collecting the beam willalso be provided.
In 'Fig. 3 a portion of the evacuated envelope of the deviceis formed by a pair of aligned tu- 'bular members '56 and 5-1 which carry respective electron permeable grids '58 and59 in the adjoining ends thereof. Grids 58 and-59 may be of the same typeas the grids shown in Fig. 1,-or of any other suitable type, and are positioned adjacent to "one another to provide a relatively narrow gap therebetween. "I'heevacuated container is maintained-vacuously continuous by means of a suitable insulating ring 6| sealed between tubes '56 and 51. Fixed to tubes 56 and 51 are respective conductingplates or-flanges62 and 63 which are similar in function and purpose to the plates II and i2 of Fig. 1. These plates 62 and 63 are adapted to retain a cylindrical shell 64 therebetween. Shelllifl corresponds to shell'34-3'| of Fig. 1. In this instance, shell 64 is illustrated as being formed of two semi-cylindrical sections, each being as shown in Fig. 4, and is provided with a plurality of small locating holes 66 which coact with corresponding holes in the plates 62 and '63, through which locating pins 'Sl'may be passed to position shell 64 concentrically surrounding the grids 58, 59 and the electron beam.
Shell 64 is then held tightly between plates 62 and 63 by means of suitable clamps illustrated 'at'6'8. It is to be understood that, if desired, the clamping arrangement of 'Fig. 1 may be utilized here, and, conversely, the clamping arrangement of Fig. '3 might be used in Fig. 1, if desired. In order to prevent impairment of the seal 6| or of the joints between the tubes 55 and 5! and the plates 62 and 63, preferably one of the plates, such as 63, is provided with a section 69 having reduced cross section which willbe relatively flexible and will prevent the transmission of strains due to clamping. It will be seen that this flexible section 69 is similar in function and purpose to the section l2 of Fig. 1.
Plates 62 and 63 may be provided with a plurality'of sets of resonator shell locating holes so that shells of'difiering diameters may be interchanged with the same apparatus to provide corresponding differing operating frequency ranges.
In the present illustration, the output concentric line H and coupling loop 12 are fixed to the permanent wall 62 of the resonator instead of to the removable wall 34 of Fig. 1. However, either of these arrangements can be utilized, in either Fig. 1 or Fig. 3, as desired. Also, Fig. 3 shows a type of tunin device for adjusting the resonant frequency of the resonator over a small range. For this purpose, a preferably conductive plug 13 is made adjustably insertable within the resonant cavity, as by means of a suitable threaded arrangement 14 in the wall '62, and will thereby adjust the resonant frequency of the resonator in the manner taught in the above-mentioned Hansen et al. Patent 2,259,690. It will be clear that a similar type of tuning adjustment may be provided in Fig. 1, if desired. Also, this tuning arrangement may be located in a removable wall, but this is less advantageous.
It will be seen that Fig. 3 therefore provides a single resonator having reentrant poles formed by tubes 56 and 51 in which the grids 58 and 59 provide a relatively narrow gap for coupling the resonator with an electron beam to be passed therethrough. The particular construction here, as in Fig. 1, permits the use of interchangeable resonator shells to vary the size of the resonator and thereby vary the desired operating frequency of the device accordingly.
Although in Figs. 3 and 4 the resonator shell 64 is shown in two separate sections, it will be understood that any suitable number of sections may be supplied as desired. Furthermore, instead of rendering these sections entirely separable, they may be hinged togethe for convenience of assembly and storage. If desired or necessary, cooling fluid may be passed through the resonator to dissipate the heat generated in grids 58 and 59 in a manner similar to that shown in Figs. 1 and 2.
As many changes could be made in the above construction and many apparently widely different embodiments of this invention could be made without departing from the scope thereof, it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
What is claimed is:
1. Ultra-high-frequency velocity-modulation apparatus comprising a pair of spaced conductive plates having aligned apertures, an electronpermeable grid fixed within each of said apertures, a conductive cylindrical member positioned between and insulated from said plates and axially aligned with said apertures and grids, said cylindrical member supporting an electronpermea'ble grid at each end thereof, whereby a pair of gaps are produced, each gap being defined by a plate grid and a cylinder grid, means vacuously sealin said cylinder to each of said plates and forming part of the evacuated envelope of said apparatus, a plurality of removable conductive members forming a cylindrical shell between and connected to said plates, said shell forming a cavity resonator with said plates, grids and cylindrical member, and means adjacent one of said gaps for protecting an electron beam successively through one of said gaps, the interior of said cylindrical member and the other of said gaps, whereby ultra-high-frequency oscillations may be set up in said resonator.
2. Ultra-high-frequency velocity-modulation apparatus comprising an evacuated envelope, means inside said envelope for projecting an electron beam through the interior of said envelope, two pairs of electron-permeable electrodes positioned in said envelope for interaction with said beam and forming two gaps to be successively traversed by said beam, each of said electrodes having connected conductive portions extending outside said envelope, and cylindrical conductive means connecting one electrode of each of said pairs to an electrode of the other of said pairs and forming a cavity resonator having a pair of gaps defined by said electrodes, whereby oscillations may be set up in said resonator by the action of said beam passing successively through one of said gaps, one of said cylindrical means and the other of said gaps.
3. Ultra-high-frequency velocity-modulation apparatus comprising an evacuated envelope, two pairs of electron-permeable electrodes within said envelope defining a pair of aligned electronpermeable gaps, conductive means exterior to said envelope and connected to all of said electrodes and forming with said two pairs of electrodes a cavity resonator having concentrated electric field portions at said two gaps, and means in said envelope for projecting an electron beam successively through said gaps to set up oscillations within said resonator.
4. Apparatus as in claim 3, wherein said conductive means comprises a conductive shell conmeeting the outer ones of said electrodes and a conductive cylinder connecting the inner ones of said electrodes, said cylinder forming a field-free drift space through which said electron beam passes between said gaps.
5. Ultra-high-frequency velocity-modulation apparatus comprising an evacuated envelope, two pairs of electron-permeable electrodes within said envelope defining a pair of aligned electronpermeable gaps, conductive means exterior to said envelope and connected to all of said electrodes and forming with said two pairs of electrodes a cavity resonator having concentrated electric field portions at said two gaps, said conductive means comprising a conductive plate connected to each of the outer ones of said grids. and a cylindrical conductive member connecting together the inner ones of said grids, a conductive sleeve slidably mounted on and contacting said cylindrical member, a conducting flange carried by said sleeve parallel to one of said plates, whereby the electric field at one of said gaps may be adjusted by adjusting the spacing between said one plate and said flange, and means in said envelope for projecting an electron beam successively through said gaps to set up oscillations within said resonator.
6. Apparatus as in claim 3, wherein said conductive means comprises a conductive plate connected to each of the outer ones of said electrodes and a multi-piece cylindrical conducting member removably connected between said plates and forming the outer shell of said resonator, whereby resonators of difiering resonant frequency may be formed by replacing said conducting member by others of different dimensions.
'7. Apparatus as in claim 3, further including means in said apparatus for adjusting the relative efiective alternating voltages across said gaps.
8. Electron discharge apparatus comprising an evacuated envelope, two pairs of electron-permeable electrodes within said envelope defining a pair of aligned electron-permeable gaps, conductive means exterior to said envelope connected conductively to said electrodes and forming velope for projecting an electron beam succes SlVBlY through said gaps, to set, up oscillations within said resonator means.
9; A high; frequency tube. structure,- comprising an evacuated. insulating; envelope, two pairs of spaced conducting grids within said envelope, meansin said envelope for setting up an electron beamfor traversing said envelope, a non-evacuated; cavity resonator surrounding said envelope, said cavity resonator having interior wall means spaced from the outer walls of said. resonator, said wall means and said outer walls. being connected to said grids to establish a pair of regions between the pairs; of grids adapted to contain alternating electric fields acting upon the electron beam, whereby one of. said fields produces. recurrent. changes in velocity of electron beam and the other of said fields produces an, interchange of energy between the beam and the resonator;
I0, Electron-discharge apparatus comprising an enclosing envelope having a tubular portion, means in said envelope for projecting an electron beam through said tubular portion along the axis thereof, a target electrode along the. path of said beam for receiving said beam, and means in, energy-interchangingrelation with said beam comprising-a pair of electrodes having closely spaced apertured portions within said tubular portion defining a. gap to be traversed by said beam, and a removable resonator-.shell-defining means exterior to said envelope and connected to said pair of' electrodes through said envelope.
1 12 An ultra-high-frequency super-heterodyne converter comprising cavity resonator means for confining an oscillating electromagnetic field having two; separate electric field portions. separated by a field-free space and having a resonant frequency, means coupled to said resonator means for supplying modulated electromagnetic energy to said resonator means having a nominal carrier frequency differing from said resonant frequency by a desired intermediate frequency, means aligned with said resonator means for passing an electron beam successively through one of said electric field portions, said field-free space and the other of said field portions, and means along the-path of said beam for detecting velocity variations, ofsaid electrons: after leaving-said last field portion, whereby a correspondingly modulated intermediate-frequency wave may be derived from saiddetector means.
12; Electron discharge apparatus comprising a tubular evacuated envelope, a pair of electronpermeable grids within said envelope, means in said envelope for projecting an electron beam through said grids, a pair of parallel conducting plates, disposed transversely of said: envelope and connected respectively to said grids, and a cylindrical. shell: surrounding said: envelope and removahly'fastenedbetween said plates and forming a cavity resonatortherewith, whereby the resonant'firequency of, said resonator may be changed y r rlacmc: said shell.
1,3. A high frequency tube structure comprising an; evacu ted insulating envelope, a pair of spaced grid structures within said envelope, means in said envelope; for; setting up an electron stream for passage through said grid struc-. tures, and a cavity resonator-having a portion remova r surr unding said envelope, said reso-- mater being coupled: to; said grid structures, wherey' S ll-d n el ctroma n ti field Within said r sonator i used t produce an, el ctric field component between said gridstructures actingupon said electron stream.
14. A high frequency tube structure comprisin an evacuated envelope, spaced grids within said envelope, means in said envelope for; setting; up an electron stream for traversing said envelope and said grids, end wall, membersfixed upon the exterior of said envelope on opposite sides of said grids, and removable wall elements insertable-between said end wall members for forming therewith a, cavity resonator adapted to contain: a standing electromagnetic field having an electric; field component between said grids.
15. A high frequency tube structure as, defined in claim 15' wherein tuning means: is; carried by one of the said fixed end wall members for'efiects ing the tuning of said resonator,
16, A high frequency tube structure; comprisingan, evacuated envelope, a pairof grid strufi-i tures within said envelope, means. in said er 1- velope for producing a beam of chargedparticljes, for successively traversing said grid; structures, and a, cavity resonator removably surrounding; said envelope and cbnductively connectedto said; grid structures through the wall of saidenvelope, said cavity resonator being adapted to contain a standing electromagnetic: field forecasting with said beam.
17. Ultra-high-frequency velocity-modulation apparatus, comprising a pair of spaced, conduc-v tiveplates having aligned: apertures, a conductive cylindrical; member-positioned between said'plates and axially aligned with said apertures, whereby a pair of gaps are formed, each gap being defined by one, of said; plates and an end of said. cylins drical member, a cylindrical shell; CQHQQQtBdyiQO; said plates and forming a cavity resonator withsaid: plates and said; cylindrical, member, means; aligned with said gap for projecting" an electron beam successively through one, of said gaps, the interior of said cylindrical member and they other of said gaps, whereby oscillations are produced within. said cavity resonator, and: means in said apparatus for adjusting the relative effective alternating voltages across said gaps, without variation of' said gaps.
l8. Ultra-high-frequency velocity-modulation apparatus comprising, a pair of 'spaced conductive plates, having aligned, apertures, a conductive cylindrical member positioned between said plates and axially aligned with said apertures, whereby a pair of gaps are formed, each gap being defined by one of said plates and an end of said, cylindri: cal member, a cylindrical shell connected to said plates and forming a cavity resonator with said plates and said cylindrical member, means alignedwith said gaps for projecting an electron beam successively through one of said gaps, the interior of said cylindrical member and the other of said gaps, whereby oscillations are produced within said cavity resonator, and means for adjusting the relative effective alternating voltages across said gaps, said adjusting means comprising a conductive sleeve slidably mounted on and contacting said cylindrical member, and a conductive flange carried by said sleeve parallel to one of said plates whereby the electric freldat one of said gaps may be adjusted by adjusting the spacing between said one plate and said flange.
19-. Ultra-high-frequency velocity-modulationapparatus, comp-rising a pair of spaced conductive plates having aligned apertures, aconductive cylinder-like member positioned between said plates axially aligned with said apertures whereby a pair of gaps are produced, each gap being defined by one of said plates and an end of said member, means sealing said cylinder-like member to each of said plates to form part of the evacuated envelope of said apparatus, cylindrical conductive means connected between said plates and forming a cavity resonator with said plates and cylinder-like member, and means in said envelope for projecting an electron beam successively through one of said gaps, the interior of said cylinder-like member and the other of said gaps, whereby ultra-high-frequency oscillations may be set up in said resonator.
20. Apparatus as in claim 19, further including means coupled to said cylinder-like memberfor dissipating electric charges accumulated by said cylinder-like member.
21. Apparatus as in claim 19, further including charge dissipating means comprising a helically wound conductor connected at one end to said cylinder-like member and having its other end forming the central conductor of a short-circuited quarter-wave concentric transmission line whose outer conductor is connected to said cylindrical means.
22. Apparatus as in claim 19 further including coaxial-transmission-line means having its outer conductor connected to said cylindrical conductive means and its inner conductor connected to said cylinder-like member.
23. Ultra-high-frequency velocity-modulation apparatus, comprisin a pair of spaced conductive plates having aligned apertures, a conductive cylindrical member positioned between and spaced from said plates and axially aligned with said apertures whereby a pair of gaps are produced, each gap being defined by one of said plates and an end of said member, conductive means connected between said plates and forming a cavity resonator with said plates and cylindrical member, means aligned with said gaps for projecting an electron beam successively through one of said gaps, the interior of said cylindrical member and the other of said gaps, whereby ultra-high-frequency oscillations may be set up in said resonator, and dissipating means coupled to said cylindrical member for dissipating electric charges accumulated by said cylindrical member said dissipating means comprising a helically wound conductor connected at one end to said cylindrical member and having its other end forming the central conductor of a short-circuited quarterwave concentric transmission line whose outer conductor is connected to said cylindrical means.
24. High frequency tube structure, comprising an evacuated envelope, a pair of spaced apertured electrodes within said envelope, a cavity resonator partially removably surrounding said envelope and coupled to said electrodes whereby a standing electromagnetic field within said resonator produces an electric field component between said electrodes, and means in said envelope for passing a stream of charged particles through said electrodes.
25. Electron-discharge apparatus, comprising means defining an enclosing vessel, means at one end of said vessel for producing an electron beam, a target electrode at the other end of said vessel, a pair of electrodes between said beam-producing means and said target electrode defining a gap to be traversed by said beam, a second pair of electrodes between said beam-producing means and said target electrode defining a second gap to be traversed by said beam, and a cavity resonator including conductive Wall means exposed to atmospheric pressure outside said vessel electrically connecting one of said first pair of electrodes and one of said second pair of electrodes and further conductive wall means also exposed to said atmospheric pressure electrically connecting the other electrodes of said pairs.
26. Electron discharge apparatus comprising cavity resonator means providing a pair of electron-permeable gaps and adapted to enclose a standing electromagnetic field having electric field portions at said gaps, and with predetermined efiective voltages, means aligned with said gaps for projecting an electron beam successively through said portions, and means in said apparatus for adjusting the relative effective voltages across said gaps.
27. Electron discharge apparatus comprising means defining an enclosing vessel, means at One end of said vessel for producing an electron beam, a target electrode at the other end of said vessel, a pair of electrodes between said beam-producing means and said target electrode defining a gap to be traversed by said beam, a second pair of electrodes between said beam-producing means and said target electrode defining a second gap to be traversed by said beam, and a cavity resonator including a wall outside of said vessel electrically connecting one of said first pair of electrodes and one of said second pair of electrodes and conductive means electrically connecting the other electrodes of said pairs.
28. Electron discharge apparatus, comprising means defining an enclosing vessel, means at one end of said vessel for producing an electron beam, a target electrode at the other end of said vessel, a pair of electrodes between said beam-producing means and said target electrode defining a gap to be traversed by said beam, a second pair of electrodes between said beam-producing means and said target electrode defining a second gap to be traversed by said beam, and a cavity resonator outside of said vessel including means electrically connecting one of said first pair of electrodes and one of said second pair of elec trodes and further including conductive means electrically connecting the other electrodes of said pairs.
29. High frequency tube structure comprising an evacuated envelope, a source of electrons within said envelope, a pair of apertured electrodes within said envelope in alignment with said source, and a further electrode in alignment with said apertured electrodes on the side thereof opposite said source, said apertured electrodes having portions extending to the exterior of said envelope and adapted to be connected to a cavity resonator whereby the electromagnetic field within said cavity resonator may produce an alternating electric field between said apertured electrodes for interaction with said electrons.
30. Electron discharge apparatus comprising means including a source of electrons for producing a stream of electrons along a predetermined path, a pair of electron-permeable electrodes mounted along said path in alignment with said source and defining a narrow gap therebetween, a pair of concentric conductive means connected respectively to said electrodes and defining therewith cavity resonator means adapted to contain a standing electromagnetic field oscillating therewithin, and means in said apparatus for adjusting the effective voltage produced by said field across said gap, said last-named means comprising a fiange member adjustably support- 13 ed on the inner of said conductive means and slidable toward and away from said gap for correspondingly adjusting said effective voltage.
WILLIAM W. HANSEN.
REFERENCES CITED The following references are of record in the file of this patent:
Number 14 Name Date Ryan May 27, 1941 Mouromtsefi et a1. Nov. 18, 1941 Hansen et a1. Oct. 21, 1941 Varian et a1 May 20, 1941 Maslov Aug. 19, 1941 Doring Sept. 2, 1941 Hahn Nov. 26, 1940 Samuel June 16, 1936 Boddie Nov. 6, 1934 Hahn Nov. 26, 1940 McArthur Mar. 18, 1941 Litton Feb. 2, 1943 Certificate of Correction Patent N 0. 2,420,314. May 13, 1947.
WILLIAM W. HANSEN It is hereby certified that errors appear in the printed specification of the above numbered patent requiring correction as follows: Column 4, line 29, strike out the Word spacing; column 7, line 68, claim 1, for protecting read pro ecting; column 10, line 15, claim 15, for the claim reference numeral 15 read 14; and that the said Letters Patent should be read with these corrections therein that the same may conform to the record of the case in the Patent Ofiice.
Signed and sealed this 16th day of September, A. D. 1947.
THOMAS F. MURPHY,
Assistant Commissioner of Patents.
US484648A 1943-04-26 1943-04-26 High-frequency resonator-tube Expired - Lifetime US2420314A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2570289A (en) * 1946-04-12 1951-10-09 Int Standard Electric Corp Velocity modulated beam tubes with reflector electrodes
US2680826A (en) * 1948-05-01 1954-06-08 Sylvania Electric Prod Stabilized klystron
US3060342A (en) * 1958-11-20 1962-10-23 Philips Corp Reflex klystron having a cavity resonator with a movable wall
DE1243787B (en) * 1955-07-08 1967-07-06 Varian Associates Tunable electron tube in the manner of a klystron

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US2795693A (en) * 1953-03-02 1957-06-11 Gen Instrument Corp Long-line tuner with variable end-loading for superheterodyne receiver
US2944187A (en) * 1955-06-14 1960-07-05 Varian Associates Electron tube apparatus
US3610338A (en) * 1969-12-16 1971-10-05 Texaco Inc Treatment of an underground formation
GB2132008B (en) * 1982-12-03 1986-06-11 English Electric Valve Co Ltd A method of altering the frequency tuning range of a klystron

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US2570289A (en) * 1946-04-12 1951-10-09 Int Standard Electric Corp Velocity modulated beam tubes with reflector electrodes
US2680826A (en) * 1948-05-01 1954-06-08 Sylvania Electric Prod Stabilized klystron
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US3060342A (en) * 1958-11-20 1962-10-23 Philips Corp Reflex klystron having a cavity resonator with a movable wall

Also Published As

Publication number Publication date
USRE23277E (en) 1950-10-03
GB581707A (en) 1946-10-22

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