US2195474A - Electron discharge device - Google Patents

Electron discharge device Download PDF

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Publication number
US2195474A
US2195474A US169770A US16977037A US2195474A US 2195474 A US2195474 A US 2195474A US 169770 A US169770 A US 169770A US 16977037 A US16977037 A US 16977037A US 2195474 A US2195474 A US 2195474A
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cathode
anode
members
discharge device
grid
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US169770A
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Winfield G Wagener
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RCA Corp
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RCA Corp
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Priority to US169770A priority Critical patent/US2195474A/en
Priority to GB29607/38A priority patent/GB519278A/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J21/00Vacuum tubes
    • H01J21/02Tubes with a single discharge path
    • H01J21/06Tubes with a single discharge path having electrostatic control means only
    • H01J21/065Devices for short wave tubes
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J19/00Details of vacuum tubes of the types covered by group H01J21/00
    • H01J19/42Mounting, supporting, spacing, or insulating of electrodes or of electrode assemblies
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J2893/00Discharge tubes and lamps
    • H01J2893/0001Electrodes and electrode systems suitable for discharge tubes or lamps
    • H01J2893/0002Construction arrangements of electrode systems

Definitions

  • My invention relates to an electron discharge device, more particularly to such a device suitable for high power output purposes at high frequencies.
  • the electrode capacitance and lead inductance In tubes intended for use for high power output purposes at high frequencies the electrode capacitance and lead inductance must be made as small as possible so that they approach the ideal of a section of a transmission line.
  • the tube must be capable of dissipating a large amount of power per unit area and of withstanding the high temperatures associated with the dissipation of these large amounts of power in order that the physical size of the tube may be small.
  • the electrons traveling between the cathode and the anode must travel short distances and must be confined to the intended short paths of travel.
  • an electron discharge device made in accordance with my inv vention is of the triode type having a multifilament cathode in which the filaments lie in acommon plane, the cathode being surrounded by a flat grid and plate.
  • the cathode and grid are supported as a unit from one pair-of terminals
  • the electron discharge device shown in Figure 1 is provided with an envelope ill and the terminal members H, l2, l3 and I4 comprising cup-shaped members sealed to the envelope proper.
  • the lower cup-shaped terminals ii and I! provide the cathode filament leads, the terminal l3 the anodelead, and the terminal it the grid lead. This arrangement permits ready incorporation of the tube in circuits of the transmission line type which are particularly suitable for high frequency work.
  • the mount assembly comprises the multi-filament cathode ii, the filaments of which lie in a common plane, and which is supported between the insulating spacer members l6 and i I.
  • the flat grid I8 surrounding the filament is supported on the grid side rods i9,mounted in the insulating spacer members it and i1 so that the lower ends may have relative movement with respect to the lower spacer il when absorption or radiation of heat from the grid side rods causes change in the length of these side rods.
  • a stop not shown may be secured to one of the side rods on the under side of spacer I! to limit movement of the grid as a whole.
  • the cathode filament and grid are supported as a unit between the spacers i6 and II, which are secured to the mount support rods or posts 20 electrically connected to and supported in turn by the channel members 2i secured to the terminals ii. and i2.
  • the mid-point 'of the cathode is connected by a conducting strap and lead 22 to one of the channel members 2i and the outside ends by a bus 23 to the other of the channel members 2
  • a flat transversely corrugated U- shaped anode 24 closely surrounds the cathode and grid and is provided along one edge with a stiffening and supporting channel member 25 to which the legs of the U-shaped anode are secured.
  • This channel member forms a portion of the anode proper.
  • This channel member is secured and electrically connected to the cupshaped terminal i3 which provides the only support for the anode 24.
  • the transverse corrugations stiffen the anode transversely and the channel member 25 provides a stiffening mem-' ber longitudinally of the anode so that the whole results in a very rigid member.
  • the upper ends of the grid side rods l9 are electrically connected together by means of a wide ribbon strap 2'6,'best shown in Figure 4, and electrically connected to the terminal II by means of the flexible strap 21.
  • This wide strap 26 which lies close to the surface of the envelope, provides a low inductance lead which may lie close to and parallel to an anode lead properly positioned externally of the envelope.
  • the terminals i3 and il render fiexibility of connection to the tube so that it can be readily incorporated in various types of circults, particularly of the transmission line type, but the wide spacing between these terminals and the cathode filament terminals insures a very low leakage loss through or across the surface of the glass when high voltages are applied to the various electrodes during operation of the tube.
  • each 80 channel member with a longitudinal slot and transverse slots 3i, as best shown in Figure 3, so that flexible fingers 32 are provided.
  • these fingers may be readily bent to conform to the position of the mount posts 20 2 and are welded to the mount post 20, the welding returning the rigidity to the channel member which it originally had before the fingers were cut into the end of the channel member.
  • a tube made according to my invention has all 5 of the desirable characteristics of an' electron discharge device intended for use at high fre quencies and is capable of dissipating large amounts of power. Because of the close spacing between the electrodes, the electrons travel short distances so that the transit times are small permitting operation at high frequencies, the shields confining the electrons so that they do not strike the wall of the envelope or reach the anode along longer paths and thus interfere with the proper operation of the tube. This results in higher plate efilciencies and charged bulb effects caused by stray electrons are eliminated. Terminals are widely spaced and leads are arranged to give low lead inductances.
  • the resulting structure provides a short heavy filament connection and the total inductance of the filament lead is greatly reduced.
  • the cathode filament lead post channels compensate for any misalignment that takes place so that the resulting tube may be accurately made and have consistent characteristics from one tube to another. Actual tests on a tube of the type described show that the tubes have normal efiiciency at frequencies up to as high as 45 megacycles, the efficiency dropping to only 60% at megacycles.
  • An electron discharge device having an elongated envelope and provided with terminal members extending from opposite ends of 15 said envelope, a multi-fllament cathode within said envelope and having the filaments lying in a common plane, and a fiat U-shaped anode surrounding said cathode and provided along one longitudinal edge with a U-shaped chan- 20 nel member to which the legs of the U-shaped anode are secured, said channel member forming part of said anode, said anode being pro-' vided with transverse corrugations, said channel member being secured to one of said terminal 25 members and serving as the sole support for said anode, said cathode being connected to oppositely extending terminal members.
  • An electron discharge device having an elongated envelope and provided with terminal 30 members extending from opposite ends of said envelope, a cathode within said envelope, a flat U-shaped anode surrounding said cathode and provided along one longitudinal edge with a U-shaped channel member to-which the legs of a the U-shaped anode are secured, said channel member forming a part of said anode, said channel member being secured to one of said terminal members and serving as a sole support for said anode, said cathode being connected to oppositely extending terminal members.
  • An electron discharge device having an elongated envelope and provided with oppositely extending terminals, a multi-fllament cathode having its filaments lying in a common plane 5 and a flat grid sin-rounding said cathode, insulating spacer members at opposite ends of said cathode and grid for supporting said cathode and grid in spaced relation, mount support rods secured to said spacer members out of electrical w 7 contact with said grid and to two of said terminals, a flat anode surrounding said grid and cathode and connected to another oi said terminal members, and transversely positioned shielding members positioned within and ad- 55 jacent the ends of said anode and extending between but out of contact with said cathode and anode and electrically secured to and supported by the mount support rods for confining electrons emitted by the cathode to the interm cathode-anode space.
  • An electron discharge device having an envelope provided with terminal members and containing cathode, grid and anode electrodes, an insulating spacer member supporting at least 55 one of said electrodes and provided with a support rod, and a channel member having a plurality of flexible fingers at one end and connected at the other end to and supported by one of said terminal members, said flexible fingers sur- 70 rounding and being welded to said support rod for supporting the insulating spacer and its associated electrode.
  • An electron discharge device having an envelope provided with terminal members and con- 7 taining cathode, grid and anode electrodes, insulating spacer members supporting at least one of said electrodes and provided with support rods, and channel members each having a plurality of flexible flngers at one end and connected at the other end to and supported by one of said terminal members, said flexible flngers surrounding and being welded to said support rods for supporting the insulating spacers and its associated electrode.
  • An electron discharge device having an envelope provided with electrode terminals sealed to and extending from the envelope, grid, cathode and anode electrodes within said envelope, one of said electrodes being provided with a support rod and lead, and a channel member secured at one end to one 0! said electrode terminals and provided at its other end with a plurality of parallel flexible flngers.
  • said support rod and lead extending transversely of and between the tingets, and being welded to said flngers whereby misalignment between said channel member and said support rod and lead is compensated for.
  • An electron discharge device including an elongated envelope, a pair of terminal members sealed to and extending from each end of said envelope, a multi-fllament cathode having its filaments lying in a common plane, a flat grid surrounding said cathode filament, said grid being provided with a pair of oppositely disposed side rods lying in the plane of said fllaments, a pair of insulating members at opposite ends of said grid side rods for maintaining said cathode filaments and grid in spaced relation, a pair of support and lead rods secured to said insulating members and channel members extending from one pair of terminal members and provided with flexible flngers engaging and secured to the support and lead rods, an anode comprising a flat U-shaped member and a U- shaped channel member secured to the legs of said U-shaped anode and forming a part of said anode and secured to one 01' the other pair 01' terminal members, said anode being supported solely by said channel shaped member, and a ribbon conducting strap secured

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  • Electron Sources, Ion Sources (AREA)
  • Discharge Lamps And Accessories Thereof (AREA)

Description

April 1940. w. s. WAGENER 2,195,474
ELECTRON DISCHARGE DEVICE Filed 001;. 19, 1937 ATTGRNEY.
, Patented Apr. 2, 1940 UNITED STATES PATENT OFFICE.
assignments, to Radio Corporation of America, New York, N. Y., a corporation of Delaware Application October 19, 1937, Serial No. 169,770
7 Claims.
My invention relates to an electron discharge device, more particularly to such a device suitable for high power output purposes at high frequencies.
In tubes intended for use for high power output purposes at high frequencies the electrode capacitance and lead inductance must be made as small as possible so that they approach the ideal of a section of a transmission line. The tube must be capable of dissipating a large amount of power per unit area and of withstanding the high temperatures associated with the dissipation of these large amounts of power in order that the physical size of the tube may be small. The electrons traveling between the cathode and the anode must travel short distances and must be confined to the intended short paths of travel.
It is therefore the principal object of my invention to provide an electron discharge device capable of large power outputs at high frequencies, which is efficient, requires a low driving power and permits flexibility in circuit design.
The novel features which I believe to be characteristic of my invention are set forth with particularity in the appended claims, but the invention itself will best be understood by reference to the following description taken in connection with the accompanying drawing in which Figure l is a side view with parts broken away and parts in section to show details of construction of an electron discharge device made according to my invention; Figure 2 is a transverse section taken along the line 2-4 of Figure 1; Figures 3 and 4 are perspectives showing details of construction of an electron discharge device made according to my invention.
The preferred embodiment of an electron discharge device made in accordance with my inv vention is of the triode type having a multifilament cathode in which the filaments lie in acommon plane, the cathode being surrounded by a flat grid and plate. The cathode and grid are supported as a unit from one pair-of terminals The electron discharge device shown in Figure 1 is provided with an envelope ill and the terminal members H, l2, l3 and I4 comprising cup-shaped members sealed to the envelope proper. The lower cup-shaped terminals ii and I! provide the cathode filament leads, the terminal l3 the anodelead, and the terminal it the grid lead. This arrangement permits ready incorporation of the tube in circuits of the transmission line type which are particularly suitable for high frequency work.
The mount assembly comprises the multi-filament cathode ii, the filaments of which lie in a common plane, and which is supported between the insulating spacer members l6 and i I. The flat grid I8 surrounding the filament is supported on the grid side rods i9,mounted in the insulating spacer members it and i1 so that the lower ends may have relative movement with respect to the lower spacer il when absorption or radiation of heat from the grid side rods causes change in the length of these side rods. A stop not shown may be secured to one of the side rods on the under side of spacer I! to limit movement of the grid as a whole. The cathode filament and grid are supported as a unit between the spacers i6 and II, which are secured to the mount support rods or posts 20 electrically connected to and supported in turn by the channel members 2i secured to the terminals ii. and i2. The mid-point 'of the cathode is connected by a conducting strap and lead 22 to one of the channel members 2i and the outside ends by a bus 23 to the other of the channel members 2| through rod 20 so that the two sections of cathode filaments are connected in parallel. A flat transversely corrugated U- shaped anode 24 closely surrounds the cathode and grid and is provided along one edge with a stiffening and supporting channel member 25 to which the legs of the U-shaped anode are secured. This channel member forms a portion of the anode proper. This channel member is secured and electrically connected to the cupshaped terminal i3 which provides the only support for the anode 24. The transverse corrugations stiffen the anode transversely and the channel member 25 provides a stiffening mem-' ber longitudinally of the anode so that the whole results in a very rigid member. The upper ends of the grid side rods l9 are electrically connected together by means of a wide ribbon strap 2'6,'best shown in Figure 4, and electrically connected to the terminal II by means of the flexible strap 21. This wide strap 26, which lies close to the surface of the envelope, provides a low inductance lead which may lie close to and parallel to an anode lead properly positioned externally of the envelope. Not only does the place- 5 ment of the terminals i3 and il render fiexibility of connection to the tube so that it can be readily incorporated in various types of circults, particularly of the transmission line type, but the wide spacing between these terminals and the cathode filament terminals insures a very low leakage loss through or across the surface of the glass when high voltages are applied to the various electrodes during operation of the tube.
During assembly the various elements are maintained in fixed position by Jigs and in order to insure an easy fit between the supporting posts or mount rods and the filament lead post channels, I provide the upper end of each 80 channel member with a longitudinal slot and transverse slots 3i, as best shown in Figure 3, so that flexible fingers 32 are provided. During assembly these fingers may be readily bent to conform to the position of the mount posts 20 2 and are welded to the mount post 20, the welding returning the rigidity to the channel member which it originally had before the fingers were cut into the end of the channel member. The result is that any slight variations in the Q relative positions of the posts in the channel members are readily taken care of so that no strains are placed upon the seals between the envelope and the cup-shaped terminals ii and 35 It is necessary to confine the electrons to the inner cathode anode space during operation of the tube. This is done by means of pairs of shield members 28 mounted within the anode adjacent the ends of the mount and extending between the cathode and the anode and are supported and electrically connected to the mount posts 20 by means of the conducting straps 29.
A tube made according to my invention has all 5 of the desirable characteristics of an' electron discharge device intended for use at high fre quencies and is capable of dissipating large amounts of power. Because of the close spacing between the electrodes, the electrons travel short distances so that the transit times are small permitting operation at high frequencies, the shields confining the electrons so that they do not strike the wall of the envelope or reach the anode along longer paths and thus interfere with the proper operation of the tube. This results in higher plate efilciencies and charged bulb effects caused by stray electrons are eliminated. Terminals are widely spaced and leads are arranged to give low lead inductances. Since the filament lead-in posts also serve as the external terminal connector posts the resulting structure provides a short heavy filament connection and the total inductance of the filament lead is greatly reduced. By making the plate of tantalum it is 55 possible to eliminate the usual getter so that the bulb is free of dielectric and charging current losses. The cathode filament lead post channels compensate for any misalignment that takes place so that the resulting tube may be accurately made and have consistent characteristics from one tube to another. Actual tests on a tube of the type described show that the tubes have normal efiiciency at frequencies up to as high as 45 megacycles, the efficiency dropping to only 60% at megacycles.
While I have indicated the preferred embodiments of my invention of which I am now aware and have also indicated only one spedfic application for which my invention may be employed, it will be apparent that my invention 6 is by no means limited to the exact forms illustrated or the use indicated, but that many variations may be made in the particular structure used and the purpose for which it is employed without departing from the scope of my 10 invention as set forth in the appended claims.
What I claim as new is:
1. An electron discharge device having an elongated envelope and provided with terminal members extending from opposite ends of 15 said envelope, a multi-fllament cathode within said envelope and having the filaments lying in a common plane, and a fiat U-shaped anode surrounding said cathode and provided along one longitudinal edge with a U-shaped chan- 20 nel member to which the legs of the U-shaped anode are secured, said channel member forming part of said anode, said anode being pro-' vided with transverse corrugations, said channel member being secured to one of said terminal 25 members and serving as the sole support for said anode, said cathode being connected to oppositely extending terminal members.
2. An electron discharge device having an elongated envelope and provided with terminal 30 members extending from opposite ends of said envelope, a cathode within said envelope, a flat U-shaped anode surrounding said cathode and provided along one longitudinal edge with a U-shaped channel member to-which the legs of a the U-shaped anode are secured, said channel member forming a part of said anode, said channel member being secured to one of said terminal members and serving as a sole support for said anode, said cathode being connected to oppositely extending terminal members.
3. An electron discharge device having an elongated envelope and provided with oppositely extending terminals, a multi-fllament cathode having its filaments lying in a common plane 5 and a flat grid sin-rounding said cathode, insulating spacer members at opposite ends of said cathode and grid for supporting said cathode and grid in spaced relation, mount support rods secured to said spacer members out of electrical w 7 contact with said grid and to two of said terminals, a flat anode surrounding said grid and cathode and connected to another oi said terminal members, and transversely positioned shielding members positioned within and ad- 55 jacent the ends of said anode and extending between but out of contact with said cathode and anode and electrically secured to and supported by the mount support rods for confining electrons emitted by the cathode to the interm cathode-anode space.
4. An electron discharge device having an envelope provided with terminal members and containing cathode, grid and anode electrodes, an insulating spacer member supporting at least 55 one of said electrodes and provided with a support rod, and a channel member having a plurality of flexible fingers at one end and connected at the other end to and supported by one of said terminal members, said flexible fingers sur- 70 rounding and being welded to said support rod for supporting the insulating spacer and its associated electrode.
5. An electron discharge device having an envelope provided with terminal members and con- 7 taining cathode, grid and anode electrodes, insulating spacer members supporting at least one of said electrodes and provided with support rods, and channel members each having a plurality of flexible flngers at one end and connected at the other end to and supported by one of said terminal members, said flexible flngers surrounding and being welded to said support rods for supporting the insulating spacers and its associated electrode.
6. An electron discharge device having an envelope provided with electrode terminals sealed to and extending from the envelope, grid, cathode and anode electrodes within said envelope, one of said electrodes being provided with a support rod and lead, and a channel member secured at one end to one 0! said electrode terminals and provided at its other end with a plurality of parallel flexible flngers. said support rod and lead extending transversely of and between the tingets, and being welded to said flngers whereby misalignment between said channel member and said support rod and lead is compensated for.
7, An electron discharge device including an elongated envelope, a pair of terminal members sealed to and extending from each end of said envelope, a multi-fllament cathode having its filaments lying in a common plane, a flat grid surrounding said cathode filament, said grid being provided with a pair of oppositely disposed side rods lying in the plane of said fllaments, a pair of insulating members at opposite ends of said grid side rods for maintaining said cathode filaments and grid in spaced relation, a pair of support and lead rods secured to said insulating members and channel members extending from one pair of terminal members and provided with flexible flngers engaging and secured to the support and lead rods, an anode comprising a flat U-shaped member and a U- shaped channel member secured to the legs of said U-shaped anode and forming a part of said anode and secured to one 01' the other pair 01' terminal members, said anode being supported solely by said channel shaped member, and a ribbon conducting strap secured to the grid side rods and connected to the other of said other pair 01' terminal members, said strap lying close to the wall of the envelope 01' said electron discharge device.
WINFIEID G. WAGENER.
US169770A 1937-10-19 1937-10-19 Electron discharge device Expired - Lifetime US2195474A (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2446460A (en) * 1944-04-07 1948-08-03 Bruce A Coffin Top cap for electron tubes
US2536636A (en) * 1946-11-15 1951-01-02 Rca Corp Lead-in conductor for electron discharge devices
US2547287A (en) * 1948-03-26 1951-04-03 Sanders Louis Liquid applicator
US2841734A (en) * 1953-03-27 1958-07-01 Gen Electric High frequency electric discharge device
US2867741A (en) * 1949-09-27 1959-01-06 Siemens Ag Electrical discharge tube

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2446460A (en) * 1944-04-07 1948-08-03 Bruce A Coffin Top cap for electron tubes
US2536636A (en) * 1946-11-15 1951-01-02 Rca Corp Lead-in conductor for electron discharge devices
US2547287A (en) * 1948-03-26 1951-04-03 Sanders Louis Liquid applicator
US2867741A (en) * 1949-09-27 1959-01-06 Siemens Ag Electrical discharge tube
US2841734A (en) * 1953-03-27 1958-07-01 Gen Electric High frequency electric discharge device

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GB519278A (en) 1940-03-20

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