US2731579A

US2731579A - Electron discharge device

Info

Publication number: US2731579A
Application number: US312185A
Authority: US
Inventors: Mortimer E Weiss
Original assignee: Sylvania Electric Products Inc
Current assignee: GTE Sylvania Inc
Priority date: 1952-09-30
Filing date: 1952-09-30
Publication date: 1956-01-17
Anticipated expiration: 1973-01-17

Description

Jan. 17, 1956 E. WEISS 2,731,579

ELECTRON DISCHARGE DEVICE Filed Sept. 30, 1952 INVENTOR MORT/MER E WEISS ATTORNEY United States--. Patent 6 ELECTRON DISCHARGE- DEVICE Mortimer E.Weiss, Flushing, N. Y., assignor to Sylvania Electric Products Inc.', a corporation-f Massachusetts Application September 30, 1952', Serial No. 312,185

8 Claims.- (ClI SIS- 249) This invention relates-to electron discharge devices; more specifically it relates to a new and'novel structure for vacuum tubes or the like.

In the early'development of vacuum tubes, the principalemphasis was placed on the production of tubes which would have given electrical characteristics. Little attention was paid to the development of improved mechanical supporting structures. The result has been that the supporting structures for vacuum tube electrodes have been mechanically weak, and have not been adapted' to automatic assembly techniques. present invention is, then, to provide a vacuum tube structure which is rugged, and adapted to automatic assembly.

Among the materials which have been continually utilized by the industry in fabricatingvacuum tubes has been g'lass',imo'st commonly utilized for the envelope of the tube. Glass has numerous disadvantages for vacuum tube purposes including a tendencyto fracture-readily, lack of machinability to cldsetolerances, etc. Also the industry has relied on'the use of mica spacers as a means for supportin'giand spacingthe. electrodes in the mount structure of the tube. Such structures are" also fragile and do not lend themselves" to the maintenance of close tolerances.

It is a furtherobjectiofltheinvention' to'provide'a'. vacuum tube capable'of productiominquantity and to close tolerances; by simplifying .and'improving the mount structure, and utilizingrnore' suitableun'a'teria'ls in the vacuum tube envelope;

Another object of' the" invention is improvement in rigidity of the electrode structure with a view'to' reducing microphonisni due to variations in:interelectrode dimensions, without, at thesametime,.regaining'the'fabrication' of electrode structures differing from those commonly employed.

A further object'of theinventionis the elimination of stresses heretofore imposed'oninte'rnal vacuum tube connecting'leads by the practice of utilizing the same leads as electrode mount supports.

The above objects and others which may occur to the reader during consideration of the below appended specificationand drawings areattained-in-the invention describedbelow and illustrated-in thedrawings in which a vacuum tube envelopeis formed-rota hollow'insulating. body having slots disposed omits-inner wall to receive portions ofthe elements comprising-T the electrode structure, the apertures through which insertion of the electrodes is accomplished being. closed by insulatinglmembers.

In the drawings:

Fig. 1 is a perspective viewofa discharge deviee ernbodying the invention;

Fig. 2 is an exploded view of the embodiment-of the invention disclosed in' Fig; i;

Fig. 3: isa view in1cross-section1ofl analternativeem bodiment of the invention shown in Fig. 2;

An object of the ice.

Fig; 4 isa view in vertical cross-section of a tube utilizing" the embodimentlsh'o'wn" in. Fig. 3;

Referring'fn'o'w to Fig? 1,. it willbe seen that the invention in one' embodiment may comprise a hermetically sealed envelope of generally rectangular configuration having central body 2 of'ceramic'or other insulating material which isclosedat either e'nd'by covermembe'rs 4, preferably also of an insulating material, and hermetically sealed to the body 2. The device is exhausted and sealed 01f through tip-off tubulatio'n 6 projecting downward from bottom cover plate 4;

Referring now to 2 in which an exploded view of a partially assembled tube embodying the invention illustrated in Fig. 1 is shown, it will be seen that the body 2 is of a generally rectangular hollow configuration having central electrode receiving. space 8. Provided in opposite faces 10, 10' of space 3 are longitudinal slots or

grooves

14, 14', 16, 16, I8, 13' and 20, 20' which are disposed generally parallel to the central longitudinal axis of member 2 Vacuum tube electrodes, such as cathode 22, first grid 24, second grid 25 and anode 28 are fitted in and supported by the pairs of grooves or

recesses

14, 14 1'6, 16, 18 18' and 20, 20' respectively. These electrodes are adapted to fit tightly within their corresponding receiving slots and ordinarily extendthe entire length of body 22 so that their ends terminate flush with the open end surfaces of body 22 and so that the lateral portions are thus fillly supported. Connections to the various electrodes are made by means of connecting leads 30 which are provided with glass beads 32 the purposeof which will be explained bel ow. The cathode 22 has a convex face 23 which bears an electron emissive coating and contains a heater coil ofconventional type. Cathode 22 is also provided with laterally projecting lugs'34" which are adapted to fit tightly into

cathode receiving slots

14, 14 and'are kept as small as possible in" order to minimize heat conduction from: thec'athode body proper to the body 2 thereby maximizing cathode efficien'cy in terms of power input peruhit area. Grid 24 has side rods 25 and is formed ofa continuous wire'wound' around the laterals 25 and is generally of a conventional'type. The second grid 26, as shown, is of'the type having lateral conductors in onlyone plane and attached to only one side of the side rods 27 and isalso of a type conventional in the vacuum tube art. Anode 28'is a simple'metallic plate, rectangular in configuration, whichv is fitted into receiving slots '20, 20'. In other respects the'specific design of'the tube'is conventional, insofar as its electrical characteristics are determined by electrode spacing-grid winding size and spacing, etc.

Assembly of the tube is accomplished by inserting the various electrodesinto their. proper slots with conducting leads projecting outwardly'from the center of the tube so as to 'locate'the'glass' beads 32 over the wall portion of body 2. The tube envelope'rnay then be completed by laying glass'sealing rings 36 between the sur faces of the'walls of body'2 and end platesfi, the entire assembly being sealed together by heating so as to cause the glassof sealingzrings'36 to flow between" the meeting surfaces of cover members 4 with body Zand to cause the glass beads 32 to'melt and merge into the seal. Upon completion of the body sealing operation, the tube may be evacuated throughtubulationi 38; the final'hermetic seal being produced by pinching otftubulation 38 in the conventional manner.

Microphonism of the tube'is considerably reduced by selecting the width of the grid, anode and cathode structures 'so' that they must be placed under a slight amount of com'pressi'on during the'p'roc'ess' of insertion into body Zan'cl will therefore, upon release of the pressure, ex pand and press tightly against the bottom portions of the 3 slots 14, 1 16, 16, etc. when in place in body 2. It is preferable, too, in designing these structures to make them of extra width so that they remain under some compression stress after insertion in the tube body. The presence of such stress in the various eleemnts reduces a tendency of the elements to vibrate and assures that they remain in position, thereby stabilizing interelectrode distances.

Referring now to Fig. 3 which shows a plan view of a body member suitable for use in an alternative embodiment of the invention, it will be seen that the body 49 has a generally cylindrical outer wall 42 and is provided with plane surface 44 at the near end of the body and a similar plane surface (not visible in the drawing) at the far end of the body, both being generally parallel to each other and generally perpendicular to the central axis of the body. Such surfaces are adapted, as in the case of the embodiment ofFig. 2, to receive end closure members in a manner similar to that already taught. The central portion of block 40 is hollowed out and provided with peripheral recesses in a configuration which may perhaps be best characterized as pinnate and thereby is adapted to receive the extremities of electrodes to be assembled and held within the block. The body 40 in this embodiment of the invention is adapted to receive the elements of a double tetrode having symmetrical, oppositely disposed sections and a common cathode. Accordingly. the general configuration of the hollowed out portion 46 is symmetrical about the center of the two tube sections, the axis bisecting the anodes 48 and being coaxial with filament 50 in the center of the tube body. The body 49 may be readily formed by moulding, casting or extruding a suitable insulating material such as a ceramic, for example. Materials which can be worked to close toler ances are preferred. 1 a

The electrodes utilized in the body of Fig. 3 comprise centrally located filament 50, double sided grid 52 which is formed on side rods 54 and which surrounds filament 50, a pair of single sided grids 56 each of which is provided with supporting side rods 59 and are located on opposite sides of filament 50, and sheet metal anodes 48 which are provided with wing portions 58. Each of the electrodes is adapted to fit into recesses in the wall of body 49, being supported thereby in place and retained under a slight degree of compression stress to increase their stability and minimize microphonism. The individual recesses and the intervening ridges or protrusions into the central space 46 of body 40 have been rounded in this instance to facilitate extrusion and to minimize any localized stresses that would be established by the presence of sharp corners. While the rounded form is preferable, it is obvious that other types of surfaces might be employed. The grid 52 may be formed in a conventional manner as was grid 24 of Fig. 2, while the standard single sided grid 26 of Fig. 2 has been modified by bending at points centrally spaced from its outer edges to provide the winged grid structure 56. The anodes 48 are also provided with wings 58 which cooperate with lateral walls 69 of anode recesses 62 to retain anode 48 in place. A certain amount of outward pressure by wings 58 on wall 60 is desirable in order to minimize motion of the anode within the recess. A getter capsule 64 may be attached to the surface of one of the anodes 48 and should be located on the side of the anode away from the electron stream. Connections to the electrodes are made in the manner disclosed in connection with Fig. 2.

The filament structure utilized in a tube embodying the body of Fig. 3 is illustrated in the cross-sectional view of Fig. 4. The tube has the body 40 of Fig. 3 sealed by end closures '68, 69 in a manner similar to that described for the tube of Fig. 2. Centrally disposed within upper ceramic closure disc 68 is a spring tensioner 66 which supports one end of the filament 50 and maintains it centered within the central space 46 of body 40. The filament 50 is of the conventional type having a metallic central core and suitable emissive coating. It is anchored at the end away from the spring tensioner in the ceramic base closure member 69 by afiixing it to a button filament lead 70. The bottom filament lead 70 is inserted through a suitable aperture in the ceramic base cap 69 and is maintained therein by means of hermetic seal 73, which may be made of glass frit, and which thus serves to rigidly maintain lead 70 in a central position in the cap.

The upper end of filament 50 is anchored to filament spring tab 72 which is in turn firmly aflixed to the lower end of filament spring 74. Filament tension spring 74 is retained in axial alignment with the filament assembly by metal exhaust tube 75, which is in turn retained in rigid position in cylindrical aperture 78 provided in upper ceramic cap 68 by hermetic seal 76. The upper end of filament tension spring 74 is anchored, in order'to main-' tain tension on the assembled filament structure, by the bead or crimp 80 in the wall of the exhaust tube, the crirnped portion being of sufficient inward extension to engage a turn of the spring coil. The upper endof tube is pinched off in the conventional manner atthe end of the evacuation process (not shown). For a better understanding of the filament structure employed herein, the reader is referred'to a copending application Ser. No. 328,701 filed on December 30, 1952, by Mortimer Weiss, entitled Electron Discharge Device and assigned to the same assignee.

Vacuum tubes constructed according to the invention are particularly adapted to facilitate assembly and permit assembly by automatic machinery techniques. The insertion of the electrodes into either of the bodies disclosed above may be conveniently performed by simple mecha-y nical devices already known in the art, sequentially ar-,

ranged to insert a given electrode as the body passes under the dispenser. Subsequent assembly of the end cover plates is. simplified and is also adaptable to performance by machinery. It should be noted, too, that the structures facilitate the assembly of vacuum tubes having different characteristics by simple, direct substitution of electrodes of the desired type, and, that variations in spacing may be readily accomplished by providing differently formed body parts. Similarly, beam forming elements may'be provided which fit the slots, in order to provide tubes having beam type characteristics. Added advantages will be found in the ability of the body wall, to

' conduct heat away from the individual electrodes through the intimate contact provided, thereby producing cooler running electrode structures. Considerable modification of the body structures is, of course, possible. For example, in some types of construction, it may be found desirable to eliminate one ofthe cover plates by providing either an integral substitute envelope portion, or by further changing the configuration of the body, portion to receive electrodes of a configuration other than rectangular. For example, the surfaces containing the oppositely facing recesses may be caused to slope towards each other, so as to provide a triangular shaped body section; alternatively, a rounded integral bottom portion may be utilized. Where it is desirable to increase the restraint applied to the electrodes, suitably recessed or ridged closure member portions may be employed, as well. Similarly, variations in the type of, recess or groove utilized may be found useful. For example, a series of small protrusions which are arranged in a line, may be substituted for a ridge, and the number of protrusions 1. An electron discharge device having a hermetically V sealed envelope, a number of electrodes having oppositely extending lateral supporting portions contained within said envelope, and said envelope having recesses oppositely disposed along substantially straight lines on its inner surface, said recesses each being adapted to engage said electrode supporting portions at a plurality of points, whereby said electrodes are maintained in predetermined, spaced relationship.

2. An electron discharge device having a hermetically sealed envelope, a number of substantially rectangular electrodes contained within said envelope, said envelope having lateral Walls containing recesses oppositely disposed along substantially straight lines on the inner surfaces of said walls and said electrodes having oppositely extending lateral supporting portions inserted in said recesses and engaging said recesses at a plurality of points, whereby said electrodes are maintained in predetermined, spaced relationship.

3. An electron discharge device including a hermetically sealed envelope, a number of electrodes within said envelope, said envelope having a generally tubular body portion, the inner surface of said body portion being defined by the motion of a directrix substantially parallel to the axis or" said tubular portion along a pinnate locus, and said electrodes having oppositely disposed lateral supporting portions adapted to engage said inner surface, whereby said electrodes are supported and maintained in predetermined, spaced relationship.

4. An electron discharge device having a hermetically sealed envelope, a number of electrodes contained within said envelope, and a number of connecting leads connected to said electrodes and passing through the Wall of said envelope, said envelope including a hollow body having generally parallel, oppositely facing recesses on the inner surface, there being an aperture for the insertion of said electrodes and a closure member for said aperture, said electrodes having laterally projecting portions adapted to be received by said recesses and to contact said closure member, whereby said electrodes are maintained in a predetermined, spaced relationship.

5. An electron discharge device having a hermetically sealed envelope, a number of substantially planar electrodes having oppositely extending lateral supporting portions contained within said envelope, and said envelope having recesses oppositely disposed along substantially straight lines on its inner surface, said recesses being adapted to engage said electrode supporting portions and to subject a number or said electrodes to lateral compressive stress, whereby said electrodes are maintained in predetermined, spaced relationship.

6. An electron discharge device including a hermetically sealed envelope, a number of electrodes sealed within said envelope, said envelope having a tubular body portion containing a number of longitudinal grooves on its inner surface, a number of said electrodes being received and maintained under lateral compression in predetermined, spaced relationship by said grooves.

7. An electron discharge device including a number of electrodes, a hermetically sealed envelope for said electrodes, said envelope having a tubular body portion, and the inner surface of said body portion having a number of longitudinal recesses, a number of said electrodes being slidably engaged under lateral compressive stress by said longitudinal recesses and maintained in a predetermined, spaced relationship thereby.

8. An electron discharge device including a hermetically sealed envelope, a number of electrodes Within said envelope, said envelope having a generally tubular portion, the inner surface of said body portion having oppositely disposed recesses being defined by the motion of a directrix substantially parallel to the axis of said tubu lar portion along a pinnate locus to provide oppositely disposed recesses, each of said electrodes having oppositely disposed lateral supporting portions conformably extending into a pair of said recesses and pressing against the surface thereof, whereby said electrodes are supported in predetermined, spaced relationship and maintained under compressive stress.

References Cited in the file of this patent UNITED STATES PATENTS 2,343,849 Binneweg Mar. 7, 1944 2,372,649 Binneweg Apr. 3, 1945 2,467,420 Binneweg Apr. 19, 1949