US2097490A - Electron discharge device - Google Patents

Electron discharge device Download PDF

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Publication number
US2097490A
US2097490A US703349A US70334933A US2097490A US 2097490 A US2097490 A US 2097490A US 703349 A US703349 A US 703349A US 70334933 A US70334933 A US 70334933A US 2097490 A US2097490 A US 2097490A
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United States
Prior art keywords
anode
control electrode
cathode
electrode
arcs
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Expired - Lifetime
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US703349A
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English (en)
Inventor
Kobel Ernst
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BBC Brown Boveri AG Germany
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Bbc Brown Boveri & Cie
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J17/00Gas-filled discharge tubes with solid cathode
    • H01J17/02Details
    • H01J17/04Electrodes; Screens

Definitions

  • This invention relates generally to electron' valve in which current is conducted through al gas or a vapor.
  • a large number of different kinds of electric valves of the vapor type are known in which current is conducted between one or more anodes and one or more cathodes through attenuated gas or vapor or sometimes through air at atmospheric pressure.
  • the iiow of current is effected almost entirely by the flow of electrons between the cathodeand the anode, such electrons Abeing primarily produced at the cathode by the thermalemission of a lament maintained at incandescence or of an incandescent spot of a mercury pool, or by other processes in valves utilizing cold cathodes.
  • the vapor contained within the valve is then :ionized by collision of such electrons to an'eri#YK charge ofthe electrons which tends to hinder I suclr ow is substantially neutralized.
  • Such valves are frequently provided with control electrodes, but although the control electrodes known heretofore were operative to preventV andto release the iiow of current through the valve in dependence upon the 'potential ofy such control electrodes; the oW of the current could not be interrupted thereby after being once established.
  • Such result is due to the fact that when a control electrode is negatively energized with respect to the associatedcathode, it becomes Ysurrounded by a sheath of positive ions which completely absorbs the potential'diiference between 'theV control' electrode and the cathode. The grid therefore becomes incapable ofpconvtrolling conditions within the valve outside of the ion sheath.
  • V means of a control electrode suitably arranged and of suitable dimensions.
  • the initiation of a discharge or arc from theV anode may then require energization ofthe control electrode ⁇ at a positive potential and this potential may advantageously be reducedl if an auxiliaryr or excitation discharge is caused to occur through the space adjacent'the vcontrol electrode.
  • excitation vdischarge als'opr'o'- vides ionized vapory in the spacebetween the anode and the control electrode during operation of the anode, thereby neutralizing the electronic space chargey in such space and decreasing the voltage drop olf the discharge. of current through the anode is interrupted by theaction'of the control electrode, the magneticl When the lilow.
  • Another object of the present invention is to provide an electron discharge device of ⁇ the gas or vapor'type in which the current ilowing from an anode to a cathode'can be interrupted by energizing a control electrode at a negative poten-v tial less'than the potential Vwhich would producey backring Aof ⁇ such electrode.
  • Another object of the present invention Vis to provide an electron discharge device of the gas or vapor type inV which the ow of current throughV an anode is initiated and maintained by the ionizing action of an'excitation'discharge.
  • Another object of the present invention is toV provide an electron discharge device of the gas or vapor type in which Voltage surges appearing on the anode are diverted over a discharge path.v
  • Another object of the present invention is to provide an electron discharge device of thegas or vapor type in whichra portion of the discharge path maybe deionized to permit control and interruption of the discharge.
  • Fig. 1 illustrates, in cross-section,V an. anode A structure forv an electron discharge device havlng a ⁇ control electrode and an auxiliaryv elecfcause the discharge to occur only ⁇ present invention
  • Figs. 8 and 9 illustraterate a portion of another embodiment of the present invention utilizing separate deionizing electrode.
  • Fig. 10 Vdiagramrnatically illustrates an example of one of the numerous possible'connectionsof an electron discharge device constructed in accordance with the present invention and utilized as an alternating current rectier.
  • reference numeral IIV designates the casing wall of a discontinuously controllable electron discharge device such as an.
  • An insulator bushing I2 extends lthrough such aperture and is supported from wall II by suitable means such as a split collar I3 bolted on the wall.V
  • suitable means such as a split collar I3 bolted on the wall.V
  • the joint between wall I I and insulator I2 is'sealed by vany means known in the art whereby a gas tight joint wmay be obtained.
  • VInsulator I2 supports an anode I4 having a stem portion extending through the insulator and a head portion receiving the discharge. The head portion of the anode is pressed against the lower part of the insulator by suitable means (not shown) and the anode is sealed against the insulator in any suitable manner.
  • anode I4 maybe constituted of any suitable conductive materials and g may be constructed with a plurality of separate portions of diierent materials.
  • Anode I4 willY 'K generally present a cylindrical surface Iand an end 'surface lI'I although anodesof anyother suitable shape and construction Vmay be used.V
  • control electrode I8 is associated with a control electrode generally designated I8 having dimensions to be more particularly specied hereinafter.
  • control electrode" I8 is represented as comprising a perforated plate I9 pro- Videdjwith reinforcing' ribs and supported from insulator I2 by an unperforated 'cylinder 2
  • ring 22 is sealed against insulator I2 by a sealing ring 24.
  • the discharge alsoV comesinto Contact with an auxiliary electrode 26 herein 'constituted bya plate'having large perforations and reinforced by .a ring 21.
  • VElectrode 26 is supported within a discharge guide 28 by means of suitable insulators 29. Electrodes I9 and 26 are connected with suitable energizing means through insulated leads 3I. Guide 28 is preferably supported from insulator I2 in sealing engagement therewith to through the lower part of the guide. Y
  • plateV I9'of control electrode i8 ⁇ is replaced by a perforated plate 32 provided with a pluralityV of parallel fins 33 constituting collecting surfaces for the charges of positive ions present in theV space between the anode I4 and control electrode I8.
  • control electrode ⁇ I8 consists of finnedplate 32 and of a cylindrical portion 3l'made in two .parts attached to plate 32 by means of ja ring 39,
  • Vand 7 but not provided with'interior ns.
  • Cylinder 3'I is provided with a plurality of annular iins 38 having the same purpose as ns 33 of plate 32 and is preferably perforated in the same manner as the plate.
  • Anode I4 may be provided with parallel fins 42 occupying the spaces between ns 33 and with annular ns 4I occupying the spaces between ns 38.
  • Sand 9 control electrode I8 comprises a cylindrical portion 43 and a'plate 4'I similar to cylinder 3'I and ⁇ plate'32 of the embodiment illustrated in Figs. 6
  • such fins are replaced by a separate ion collectingV electrode structure 44 comprising a plurality of annular members supported on cylinder 43 by means of insulators 43 and a plurality of rectilinear'members supported in plate 4'I by insulators 49.
  • the electrode structure 441s connected Withra suitable energizing means to be described hereinafter by source.
  • the positive charges of the ions present overa portion of the length oi the discharge path such as for instance V in the space betweenuthre anode and the control electrode, must be largely eliminated.
  • the ionic charges within such space must v be removed at a rate greater than the rate of appearance of such chargesas the result either Vof collisions of the electrons with vapor atoms therein or of wandering of ions from the space outside the control electrode through the openings thereof.
  • the control electrode becomes operative toV control or to completely interrupt the flow of electrons therethrough, the complete interruption being obtained by impressing a suitable negative potential on the control electrode to prevent any further transport of charges at the anode'.
  • control ⁇ electrode is unenergized or is energized at negative potentials of any magnitude with'respect to the associated cathode.
  • the openings of the control electrode should preferably be of dimensions less than twice the mean free path of the electrons in the device to substantially prevent ionization by collision within such openings and thus facilitate the deionizing action of the electrode. total area of such openings must also be limited and should preferably not exceed 40% of the areak of the anode carrying the discharge.
  • the distance between the control electrode and the anode should be comparable with the mean free path of the electrons, butV should not exceed fifty times the greatest dimension of such openings.
  • the area of the control electrode in Contact with the space contained between such electrode and the associated anode, plus the total area of the surfaces of such control electrode forming the openings thereof, which surfaces jointly operate to collect the charges of positive ions present in the space between the control electrode and the anode, should be greater to a variable extent than the total cross-section area of such openings.
  • the lower limit of the ratio of such areas varies with the distance between the control electrode and the anode and should exceed the value 2.5 in a device utilizing mercury vapor when such distance is equal to the mean free path of the electrons. It will be understood that such dimensions are given only as an example of constructions which have been found successful by experiment but that vsuchdimensions Vand the Y arrangement of the control electrode may be departed from to a considerable extent. Withthe above dimensions, it is possible to interrupt current through an anode by impressing on the control electrode a negative potential less than the amplitude of the positive potential of the anode immediately after interruption of the current therethrough.
  • control electrode I8 may be impaired if the space adjacent such control electrode contains appreciable amounts of gases or vapors other than the operating vapor. It is, therefore, advantageous to make the control electrode of materials which do not easily adsorb gases or vapors and from which, therefore, gases orV vapors are released in only inappreciable amounts at operating temperatures. materials particularly suitable for the construction of the control electrode are metals or alloys such as nickel, nickel steel, chrome nickel steel,
  • control electrode is preferably made by casting or sintering such metals in vacuumV and may be subsequently heat treated in vacuum to further decrease the foreign gas content of the material.
  • a discharge device 50 is diagrammatically represented as being of the type having a mercury pool cathode 58 and as being provided with a plurality of anode structures similar to anode I4 with the associated control electrode I8, and also provided with' electrodes The.:
  • Each anode I4 is connected with the associated electrode 26 through'a resistor 55, and is connected with the associated control-electrode Iii-through one of the segments cfa distributo-r ⁇ 5l having a brush driven by'a synchro-
  • Each con-l trol electrode I8 is further connected with a ⁇ - source of negative potential with respect to cathode 6E such as battery 63 through onev of the contacts of a distributor 59 driven by a synchronous motor 5I' energized from line ⁇ 52.
  • each such electrode is connectedv with a'suitable point of battery 63 either'directly or through a distributor 62 operating in conjunction with distributor 59.
  • Synchronous motors 58 and 6I are each provided with a plurality Aof eld windings receiving exciting current from line 52 through rectifying devices 66 and a regulating device 54 to adjust the moments of energization of the several electrodes of device iI during the voltage cycle of line 52.
  • anode I4 receives, from transformer 53, an alternating voltage recurringly bringing such anode to a positive potential with respect to cathode 5i).
  • Electrode 26 is then likewise brought to a positive potential and carriesr lot:
  • control electrode I8 a Vcurrent limited by resistor 55, which ionizes and of control electrode I8 with battery 6 ⁇ 3 is eifected through distributors 52 and 59.Y
  • the charges of the ions present between control electrode I8 and anode I4 are removed at a rate greater than the rateof appearance of such ions within such space f by collision or by Wandering through the control electrode apertures.
  • the device is deionized by either the control electrode alone or the control electrode in'conjunction with an auxiliary electrode, such deionization may be elected by the auxiliary electrode alonefor by any other suitable means.
  • the control of the electronic discharge may'also be eiected by any suitable means other f than the control electrode illustrated in the above described embodiments. If the control electrode is used, it has been found sucient to deionize the space on one side only of such control electrode, but if so desired, the space on both sides of the control electrode may likewise be deionized by the provision of charge collecting surfaces or of equivalent means.
  • the control ,electrode completely encloses the anode head, but where a discharge guide suchas guide 28 illustrated in Fig. l yis provided, such discharge guidemay cooperate with the control electrode in separating the space surrounding the anodeV head from the space between the control electrode and the cathode.
  • an electron discharge device of the vapor arcing type the combination of a cathode, an anode constituting with said' cathode spaced electrodes forthe ilow of current by way of arcs than the length of the mean free path of electrons involved insustaining said arcs and having apertures defined by opposite surfaces distant not more than twice the thickness of ionsheaths produced within said apertures when subjected to potential more negative than the potential of said cathode.
  • an electron discharge device of the vapor arcing type the combination of a cathode, an anode constituting with said cathode spaced electrodes for the flow of current by way of arcs therebetween, and means for controlling said flow of ⁇ current by interruption of said arcs during Vperiods when said anode and cathode are subjected torpotential differences of sign and magnitude suflicient to maintain said arcs comprising a control electrode having a surface thereof positioned from the arcing surface of said anode a distance not greater than the length of the mean free path of the electrons involved in sustaining said arcs, and having a plurality of apertures constituting paths for the ow of said current cfa total cross section area of approximately forty percent of the arcing surface'of said anode.
  • a control electrode having a surface thereof positioned at a distance from the arcing surface of said anode not greater than the length of the mean free path of the electrons involved in sustaining said arcs and having a plurality of apertures forming paths for the flow of said current and of such cross section area that the distance between opposite surfaces defining the same is not greater than twice the thickness of ion sheaths produced therein when subjected to a potential more negative than the potential of said cathode, and means comprising an auxiliary electrode having connection with said anode and so positioned relative to said cathode as to constitute therewith spaced electrodes for the discharge of voltage surges occurring upon the said interruption of said arcs.
  • an electron discharge device of thevapor arcing type the combination with an electron emitting cathode supported in contact with a body of ionizable vapor, and an anode positioned to receive electrons from said cathode ionizing said vapor and constituting with said cathode spaced electrodes for the flow of current by way of arcs through said Vapor, of means for controlling said flow of current by interruption of said arcs during periods when said anode is subjected to potential of sign and magnitude sufficient to maintain said arcs comprising a, control electrode having ,a surface thereof positioned at such a distance from the arcing surface of said anode as to deionize the space therebetween when subjected to a potential more negative than the potential of said cathode, and having a plurality of apertures forming paths for the ow of said current of such cross section area that the distance between opposite Surfaces defining the same is not greater than twice the thickness of 40 ion sheaths produced therein when subjecte
  • an electron discharge device comprising an evacuated chamber having a cathode of vaporizable material and an anode supported thereon and constituting with said cathode spaced electrodes for the flow of current by way of arcs therebetween, and a shield supported within said chamber about said anode and forming a guide for said arcs, of means forV controlling said flow of current by controlling the initiation and interruption of said arcs during periods when said anode and cathode are subjected to potential differences of sign and magnitude sufficient to maintain said arcs comprising a control electrode supported within said shield with a surface thereof positioned from* f the arcing surface of said anode at a distance not greater than the. length of themeancfree path of electrons involved in sustaining said arcs and having apertures' defined by opposite sur-

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US703349A 1932-12-24 1933-12-21 Electron discharge device Expired - Lifetime US2097490A (en)

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DE430915X 1932-12-24

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US (1) US2097490A (enrdf_load_stackoverflow)
BE (1) BE400427A (enrdf_load_stackoverflow)
FR (1) FR765780A (enrdf_load_stackoverflow)
GB (1) GB430915A (enrdf_load_stackoverflow)
NL (1) NL36870C (enrdf_load_stackoverflow)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2456855A (en) * 1944-10-02 1948-12-21 Westinghouse Electric Corp Unitary multiple spark-gap device
US2490542A (en) * 1944-01-14 1949-12-06 Gen Electric Mercury arc rectifier
US2494895A (en) * 1945-05-02 1950-01-17 Hartford Nat Bank & Trust Co Electric discharge tube with protected electrode inlet
US2512538A (en) * 1949-07-26 1950-06-20 Atomic Energy Commission Electric discharge device
US2929947A (en) * 1953-02-17 1960-03-22 Elektrophysikalische Anstalt Lead-in for electric currents in gas discharge vessels
US3437863A (en) * 1965-07-29 1969-04-08 Filipp Ivanovich Butaev High-voltage mercury-arc rectifier

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2490542A (en) * 1944-01-14 1949-12-06 Gen Electric Mercury arc rectifier
US2456855A (en) * 1944-10-02 1948-12-21 Westinghouse Electric Corp Unitary multiple spark-gap device
US2494895A (en) * 1945-05-02 1950-01-17 Hartford Nat Bank & Trust Co Electric discharge tube with protected electrode inlet
US2512538A (en) * 1949-07-26 1950-06-20 Atomic Energy Commission Electric discharge device
US2929947A (en) * 1953-02-17 1960-03-22 Elektrophysikalische Anstalt Lead-in for electric currents in gas discharge vessels
US3437863A (en) * 1965-07-29 1969-04-08 Filipp Ivanovich Butaev High-voltage mercury-arc rectifier

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NL36870C (enrdf_load_stackoverflow)
GB430915A (en) 1935-06-27
FR765780A (fr) 1934-06-15
BE400427A (enrdf_load_stackoverflow)

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