US2299792A - Electric discharge tube - Google Patents

Electric discharge tube Download PDF

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Publication number
US2299792A
US2299792A US276012A US27601239A US2299792A US 2299792 A US2299792 A US 2299792A US 276012 A US276012 A US 276012A US 27601239 A US27601239 A US 27601239A US 2299792 A US2299792 A US 2299792A
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Prior art keywords
electrons
cores
anode
voltage
electron
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US276012A
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English (en)
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Bouwers Albert
Berg Aart Van Den
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Hartford National Bank and Trust Co
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Hartford National Bank and Trust Co
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05HPLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
    • H05H11/00Magnetic induction accelerators, e.g. betatrons

Definitions

  • X-ray tubes are known in which the. electrons on their way from the cathode to the anode are. accelerated, not by a voltage applied between two
  • Another object of our invention is to construct in practice discharge tubeswith Faraday electron accelerationwithout' repeated circulation of
  • a further object' of our invention is to con struct discharge utbes with Faraday electronac celeration with rectilinear discharge path.
  • the well-known arrangement for securing such an electron acceleration comprises a transformer whose secondary winding is formed by the discharge path of the tube.
  • the voltage induced in a single turn is only low, but the tube is constructed as a closed ring so that the electrons, after. moving about the magnetic flux, again traverse the same path and thus increase their speed.
  • the electrons acquire a speed corresponding to the voltage set up in a secondary of it turns.
  • a magnetic transverse field is provided to impart to the electrons an acceleration directed towards the center of the ring. This ensures that the electrons pass many times around the magnetic flux in a spiral-shaped path until they impinge at a high speed upon the anode where they produce X-rays.
  • the invention employ a device for Faraday electron acceleration in which the iron core is divided into a plurality of iron cores, and provide an energizing coil for each core.
  • the speed of an electron corresponds to a voltage which is n times greater than that obtained in the wellknown arrangement after one circulation.
  • the invention is a particular case of using a transformer in which the ratio between the secondary voltage V2 and the primary voltage V1 is In which is designates the numberof iron cores forming the magnetic body of the transformer, and m and n1 designate the number of turns in the secondary and the primary windings respectively.
  • Fig. 1 is a sectionalized diagrammatic view of a tube according to the invention in which the discharge beam has a rectilinear axis,
  • Fig. 2 is a section along line 2 2 of Figure 1
  • Fig. 3 is a sectionalized diagrammatic view of. a tube having a discharge path closed. on itself,
  • Fig. 5 is a side-view of a portion of a discharge tube embodying the invention.
  • Fig. 6 is a section of a discharge deviceacc'ord ing to the invention the effective parts of which are all located in an evacuated space.
  • Fig. 7 is a section through line 5-5 of Fig. 6,
  • Fig. 8 is a section through a portion of the de vice shown in Figs. 6 and 7.
  • the electrons emitted by cathode 2 are moved into the path of the discharge by the electric field set up between the cathode 2 and the suction anode 21 by means of a source of E. M. F. shown as a battery 28. Subsequently the electrons are propelled towards anode 4 by the resulting force, which is proportional to in which indicates the magnetic flux in one core and k the number of cores.
  • a magnetic longitudinal field which, as is well known, can influence the direction of flow of the electrons.
  • a construction such as shown in Figure 5 may be used.
  • FIG 5 only a portion of the toroidal tube 7 of Figure 3 is shown.
  • the tube is surrounded, in the manner shown in Figure 3, by a plurality of iron rings I! which are slotted at l8, and are provided with coils (not shown).
  • the slots I B which are preferably so narrow that the resulting increase in reluctance of the magnetic circuit of the rings is no greater than in the case of butt joints used in transformers, produce two mutually-insulated ends on each of If the same voltage were to be induced by a single primary winding surrounding all the cores, a lctimes larger primary voltage would have to be applied in order to pass the magnetizing current necessary for this purpose through this winding.
  • the magnetizing current is supplied k times and the intensity of the same increases correspondingly, but a lower voltage can be applied to the primary windings.
  • reference numeral 1 designates a toroidal discharge tube having an incandescible cathode 8, a collecting device 9 arranged towards the inner side of the tube, a suction anode l0 and a main anode [3.
  • An alternating voltage produced by a generator 24 is applied between cathode 8 and the apertured suction anode Ill arranged in front of the collecting device.
  • the tube is surrounded by a plurality of iron rings [2 provided with coils II which are energized by an alternating voltage in synchronism with the voltage produced by generator 24 so that the electric force brought about by the alternating magnetic field points in the direction of the cathode towards the suction anode during the half-cycles of the alternating current in which the suction anode II] is positive with respect to cathode 8.
  • the coils H may be connected in parallel across generator 24.
  • a magnetic system having annular pole pieces I4 and 15 arranged within the tube (see Fig. 4).
  • This system further comprises, pole pieces 25 provided with a coil I6 energized from a current source 26, shown as a generator. Due to the division of the iron into 19 cores the voltage required for each of the coils H is again low.
  • the increase in speed of the electrons may be substantially high for each circulation thereof than with the well-known tube comprising a simple primary so that fewer circulations are required to obtain a, given speed.
  • the Wave form of the energizing current of coil l6 should preferably be adapted to that of the energizing current of coils H.
  • the electrons start at a speed substantially equal to zero or a constant speed. In these cases there is only one very small moment in which conditions are favourable for the electrons to reach the anticathode. Electrons starting before or after that moment meet a magnetic field of such a strength that it bends the path of the electrons so as to impinge on the tube wall.
  • the value of the magnetic field between the pole pieces M and 15, the volt-' age between the anode I0 and the-cathode 8 and the radius of the circle on which the aperture of anode H1 is situated, should correlate" in such a manner that the centripetal force. on the electrons that have just passed through anode 8, which force depends on the velocity of these electrons and the strength of thelatff eral magnetic field, is substantially equal' to the force by which an electron having the said velocity'is kept running in a circularpath with a radius equal to the distance of the anode. aper ture from the centre of the circular. system. Dur ing the course of the electron in the'dischargepath it is accelerated by the variable field of the cores l2.
  • the centripetal force growing on only'due to the increase of the tangential velocity of the electrons would not be capable of keeping the electrons in a circular path. Consequently the path of the electron would be a spiral the radius vector of which would be about proportional to the electron velocity.
  • the magnetic force H, necessary for keeping an electron having a tangential velocity v in a circular path with a radius T is equal to H: yT m/(l gauss wherein ,c v/c and c is the velocity of light propagation.
  • This equation dc-stine s the voltage with which at a given magnetic force of the lateral field the electrons starting on a circular path are prevented from immediately deviating from this path.
  • Figs. 6 and 7 show a device according to the invention wherein the accelerating coils as well as the coils producing the Lorentz-force are enclosed in the vacuum. There is no separate toroidaltube as in the case of Figs. 3 and l.
  • ring-shaped magnetic cores 32 of laminated iron, alternating with solid magnet bodies 33.
  • Each of the cores 32 carries a set of two coils 3 4, connected in se ries by a wire 35.
  • Cores 32 and coils 34 correspend with cores l2 and coils ll of Fig. 3.
  • the magnet bodies 33 are provided with poleshoes 35 between which a magnetic field may be produced having its lines of force parallel to the axis of the cylindrical housing. This magnetic field serves for producing the Lorentz-force that counteracts the centrifugal force of the electrons.
  • Each of the magnet bodies 33 carries a set of two energizing coils 31, connected in series by a wire 38.
  • the sets of coils 37 are electrically connected to current leads 38 and so as to be connected in parallel and the sets of coils 34 are connected likewise to current leads 4
  • Lead 43 is connected at 48 with the grounded housing 30.
  • an electrode system construction 51 mounted in the housing is an electrode system construction 51, shown at an enlarged scale in Fig. 8.
  • This system comprises a coiled filamentary cathode 43 surrounded by a focussing device 19.
  • the latter is again mounted within a casing 55 having a slit 5
  • the casing 50 is secured and electrically connected to the grounded cores 32. It is made of a non-magnetic metal and extends between two cooperating pole-shoes of one of the bodies 33.
  • Device 45 is supported from a high voltage insulator 52 by a metal tubular member 53, extending within a tubular member 54 of insulating material.
  • Member 53 encloses wires 55 and 56 constituting the heating current supply leads of cathode 58.
  • Wires 55 and 55 and member 53 are insulated from each other for low tension, but they are insulated from housing 30 for high tension.
  • Three wires 51, 58 and 59 project from insulator 52 connected to wires 55 and 56 and to member 53 respectively.
  • wires 55 and 55 are connected to a source of heatingcurrent 63 for cathode 48, shown as a battery and wire55 and member 53 are connectedto the ends of a source of low tension, shown as a battery 5
  • a wire 62 leads to the negativeterminal of a high voltage direct current generator (not shown) the positive terminal of which is grounded.
  • the negative voltage supplied-to the cathode 6.3 may be kv. e. g.
  • housing 30 is highly evacuated.
  • a connection for a high vacuum pump (not shown) is provided at 63.
  • anticathode 54 Secured to the cylindrical wall of housing 35 is an anticathode 54 comprising a target 65 extending between the pole-shoes of one of the magnet bodies 33. Means areprovided for supplying the anti-cathode with cooling liquid and indicated at 56.
  • Wires 44 and 45 are connected to a source of current 51, producing alternating voltage of e. g. 500 cycles. Thereby an alternating magnetic field is produced in the cores 32.
  • High voltage is applied between cathode 48 and anode 53, the anode being positive. This causes a beam of electrons emerging from the slit 5
  • the longer dimension of the slit is parallel to the cylinder axis of the housing and the shorter dimension is in the radial direction. Consequently a band shaped beam of electrons is produced having the longer side of its section directed parallel to the axis of housing 38.
  • a window 65 is provided in the cover.
  • the velocity of the electrons may be considerably increased because there are a plurality of accelerating coils provided and the action of all of these coils has a cumulative effect.
  • an electric discharge tube including means to produce a stream of electrons within the tube, and a device for producing Faraday acceleration of the electrons
  • a device for producing Faraday acceleration of the electrons within the tube including a plurality of iron cores of annular shape surrounding said tube and each provided with a slot to form two mutually-insulated ends, an energizing coil for each core, means electrically interconnecting said cores in series to form a coil thereof, and means to pass a current through said cores to thereby produce a magnetic field within the tube and substantially coaxial therewith.
  • an electron discharge device a plurality of looped iron cores, an energizing coil on each core, said cores being so arranged as to enclose a ring-shaped space, an electrode system including a cathode and a perforated anode spaced apart so as to produce a beam of electrons emerging from said anode within said ring-shaped space in a tangential direction, means for producing a lateral magnetic field exerting on the electrons a centripetal force and an anticathode in said space for receiving the electrons accelerated by said cores when alternating current is supplied to said coils.
  • an electron discharge device a plurality of looped iron cores, an energizing coil on each core, said cores being so arranged as to enclose a ring-shaped space, an electrode system including a cathode and a perforated anode spaced apart so as to produce a beam of electrons emerging from said anode within said ring-shaped space in a tangential direction, means for producing a lateral magnetic field of varying strength, exerting on the electrons in said ring-shaped space a varying centripetal force and means for applying a varying electron genearting voltage between said cathode and anode.
  • an electron discharge device a plurality of looped iron cores, an energized coil on each core, said cores being so arranged as to enclose a ring-shaped space, an electrode system including a cathode and a perforated anode cooperating with said cathode so as to produce a beam of electrons emerging from said anode within said ring-shaped space in a tangential direction, means for producing a lateral magnetic field of varying strength, exerting on the electrons in said ring-shaped space a varying centripetal force, means for applying a varying electron generating voltage between said cathode and anode and means for interrupting the beam of electrons during selected time intervals.
  • an electron discharge device a plurality of looped iron cores, an energizing coil on each core, said cores being so arranged as to enclose a ring-shaped space, means for producing a beam of electrons in said space at a certain distance from the axis thereof in a tangential direction with an initial velocity, means for producing a magnetic field having the value whereby electrons having the initial velocity are caused to travel in a circular path having a radius equal 5 being the quotient between the velocity v and the light propagation velocity.
  • a hermetically closed vessel a plurality of looped cores of laminated iron, an energizing coil on each core, said cores being so arranged as to enclose a ring-shaped space, first means for producing a tangentially directed beam of electrons in said space, second means for producing an axially directed magnetic field in said space and an anti-cathode mounted at the outer periphery of said space, means for highly evacuating said vessel and sources of voltage for energizing said coils and first means.
  • an electric discharge device comprising an evacuated container, means for producing a beam of electrons in said container, and means for producing a varying magnetic field having lines of force encircling the electron beam to thereby produce Faraday acceleration of the electrons, said latter means comprising a large number of ring-shaped magnetizable cores surrounding the electron beam and a large number of energizing coils, each coil encircling the corresponding core to produce annular magnetic lines of force therein.
  • an electric discharge device comprising an evacuated container, means for producing a beam of electrons in said container, and means for producing a varying magnetic field to thereby produce Faraday acceleration of the electrons, said latter means comprising a plurality of ring-shaped magnetizable cores surrounding the electron beam and an energizing coil for each of said cores, said coils being connected in parallel.
US276012A 1938-05-31 1939-05-26 Electric discharge tube Expired - Lifetime US2299792A (en)

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DE212276X 1938-05-31

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US (1) US2299792A (fr)
BE (1) BE434611A (fr)
CH (1) CH212276A (fr)
FR (1) FR855502A (fr)
GB (1) GB520820A (fr)
NL (1) NL54683C (fr)

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2473477A (en) * 1946-07-24 1949-06-14 Raythcon Mfg Company Magnetic induction device
US2489082A (en) * 1944-07-01 1949-11-22 Forest Lee De High-voltage generator
US2520383A (en) * 1944-10-18 1950-08-29 Invex Inc Ultra high frequency oscillator
US2572551A (en) * 1943-09-01 1951-10-23 Bbc Brown Boveri & Cie Magnetic induction accelerator
US2736799A (en) * 1950-03-10 1956-02-28 Christofilos Nicholas Focussing system for ions and electrons
US2748339A (en) * 1951-08-17 1956-05-29 Rudenberg Reinhold Charged particle a. c. generator
US2882396A (en) * 1953-10-30 1959-04-14 Ernest D Courant High energy particle accelerator
US2892962A (en) * 1955-10-07 1959-06-30 Karl F Ross Electronic lens system
US2898508A (en) * 1957-06-13 1959-08-04 George E Mallinckrodt Charged-particle accelerator
US2931939A (en) * 1958-06-24 1960-04-05 Nicholas C Christofilos Electron gun
US2953750A (en) * 1956-09-04 1960-09-20 Nicholas C Christofilos Magnetic cable
US2976444A (en) * 1958-06-23 1961-03-21 Gen Dynamics Corp Coupling device
US2993851A (en) * 1953-01-14 1961-07-25 Thomson George Paget High temperature and neutron producing system
US3170841A (en) * 1954-07-14 1965-02-23 Richard F Post Pyrotron thermonuclear reactor and process
US6084353A (en) * 1997-06-03 2000-07-04 Communications And Power Industries, Inc. Coaxial inductive output tube having an annular output cavity

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2572551A (en) * 1943-09-01 1951-10-23 Bbc Brown Boveri & Cie Magnetic induction accelerator
US2489082A (en) * 1944-07-01 1949-11-22 Forest Lee De High-voltage generator
US2520383A (en) * 1944-10-18 1950-08-29 Invex Inc Ultra high frequency oscillator
US2473477A (en) * 1946-07-24 1949-06-14 Raythcon Mfg Company Magnetic induction device
US2736799A (en) * 1950-03-10 1956-02-28 Christofilos Nicholas Focussing system for ions and electrons
US2748339A (en) * 1951-08-17 1956-05-29 Rudenberg Reinhold Charged particle a. c. generator
US2993851A (en) * 1953-01-14 1961-07-25 Thomson George Paget High temperature and neutron producing system
US2882396A (en) * 1953-10-30 1959-04-14 Ernest D Courant High energy particle accelerator
US3170841A (en) * 1954-07-14 1965-02-23 Richard F Post Pyrotron thermonuclear reactor and process
US2892962A (en) * 1955-10-07 1959-06-30 Karl F Ross Electronic lens system
US2953750A (en) * 1956-09-04 1960-09-20 Nicholas C Christofilos Magnetic cable
US2898508A (en) * 1957-06-13 1959-08-04 George E Mallinckrodt Charged-particle accelerator
US2976444A (en) * 1958-06-23 1961-03-21 Gen Dynamics Corp Coupling device
US2931939A (en) * 1958-06-24 1960-04-05 Nicholas C Christofilos Electron gun
US6084353A (en) * 1997-06-03 2000-07-04 Communications And Power Industries, Inc. Coaxial inductive output tube having an annular output cavity

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Publication number Publication date
CH212276A (de) 1940-11-15
BE434611A (fr)
FR855502A (fr) 1940-05-14
GB520820A (en) 1940-05-03
NL54683C (fr)

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