US2482826A

US2482826A - Filament structure for thermionic tubes

Info

Publication number: US2482826A
Application number: US608960A
Authority: US
Inventors: Bender Harry; William B Voorhis
Original assignee: Tung Sol Lamp Works Inc
Current assignee: Tung Sol Lamp Works Inc
Priority date: 1945-08-04
Filing date: 1945-08-04
Publication date: 1949-09-27
Anticipated expiration: 1966-09-27

Description

Sept. 27, 1949. BENDER ET AL I 2,482,826

FILAMENT STRUCTURE FOR THERMIONIC TUBES Filed Aug. 4, 1945 2 Sheets-Sheet l 1 N V EN TOR. HA Rf? y BEA/DER W/L L IAM 5. VOORH/S BY 6 11 1111, W, M? THE//? A 7'TORNEYS S 1949- H. BENDER ET AL 2,432,826

FILAMENT STRUCTURE FOR THERMIONIC TUBES Filed Aug. 4, 1945 2 Sheets-Sheet 2 IIIIL L Z J FIG. 8

IN V EN TOR.

(H RR) BENDER BY ILL/AM B. VOORH/S mw ww THE/R A TTORNEYS Patented Sept. 27, 1949 UNITED STATES PATENT OFFICE j 1 2, 482,826 V FILAMENT STRUCTURE FOR 'rnERMIoNIoj 1.. TUBES Harry'Bender, Bloomfield, and William B. Voorhis, Scotch Plains, N. J., 'assignors to Tung-Sol Lamp Works, Inc., Newark, N. J a corporation re law e :Application August 4, 1945, Serial No. 608,960

This invention relatesto thermionic tubes and particularly to heating filamentsand mounts therefor, although certain features of the invention have other applications.

Heating filaments and mounts in cathode assemblies of theconventional practice are not entirely satisfactory and particularly assemblies and structures embodying comparatively long and high voltage heating filaments. The longer the filaments and finerxthe wire the less self-supporting they become andthe more difficult it is to manipulate them andito properly and uniformly assemblethe elongated filaments inside the cathodes without collapse. Difficulties are also experienced with these fine wire unstable filaments in mounting them upon and welding to the lead wires in a' manner 'so aslto obtain perfect Welds or not to impair the filaments or their terminals. J

Onev object of the invention is a filament mountingstr'ucture and cathode assembly whereby the above difficulties and others are minimized or avoided. l

A further object of the invention is a heating filament and vcathodeassembly of the above indicated character which is characterized by the firm and stable support ofthe elongated coil fila-- ment inside the cathode against collapse and by the ease of welding the filament terminals-to the lead'wires to form both a-firm support andelectrical connection and by the ease of forming the filament and assembling it'tothe mount.

' A further object of the invention is a; coiled filamentary element of the above indicated character having a novel and improved end connector or terminal 'and' support. 7 i

A further object of the invention is a novel and improved method of making heating filament units for thermionic tubes'and particularly elongated high voltage filaments which is characterized by marked economy in the use of raw materials, by a substantial reduction in the number of manufacturing stepsor operations, by the ready adaptability of the method to the makin of filamentary units embodying filaments of the fineness required for high voltage heaters and by a substantial decrease in material loss.

Further objects of the invention will hereinafter appear. a I I For a better understanding of the invention reference may be had tothe accompanying drawings forming a part of this'application, wherein bodying the invention;

Fig. 1 is'a'. side view of afthermionic tube em- Fig. 2 is a side view on'anenlarg edscale-of a is Claims. (01150-275) 2 filament mount and cathode assembly embodying the invention;

V Fig. 3 is a still further enlarged View of a part of the mount shownin Fig.2;

Fig. 4 is a view similar to Fig. 3 but disposed at right angles thereto;

Figs. 5 and 6 are sectional views along the lines 5-5 and 6-6 of Fig. 3; V

Fig. 7 is a view similar to Fig. 3 showing a modification;

Fig. 8 is a diagrammatic view illustrating steps in the making .of thefilamentary units according to the invention; and. I

Figs. 9 and 10 illustrate further steps in the method of manufacture. v

The invention is illustrated as embodied in a thermionic tube I havingtwo cathode elements, only one being shown and this one being indicated at 2 and being suitably mounted between the upper and lower insulating plates 3 and This cathode 2 is hollow and of conventional make. It may be circular in cross section or of other conventional section. In the-embodiment illustrated the cathode element 2 is tubular and circular in cross section The filament element of the filament cathode assembly is indicated at 5, this filament being of conventional coil form and of a length and fineness such that itis incapable of supporting itself in the position shown without the support afforded by the filament end structures 6 and the hollow cathode 2. This filament 5 is coated in' the conventional manner with any of the insulating materials used for that purpose so as to prevent short-circuiting of adjacent coils or the short-circuiting of any part of the filament by coming in contact withthe interior surface of the metallic cathode 2. At 1 are shown the lead or support wires extendingfrom the press of the tube with their ends 1 turned overat an angle and fastened to the end structure 6 of the filament 5 as, for example, by welding;

In Figs. 3, 4, 5 and 6 are illustrated the supporting end structures or terminals of the coiled filament 5. Eachof the terminals 6 is provided with a cylindrical'supporting part 8 which is of substantially-the same diameter as the diameter.

3 9 which is formed integrally with the supporting part 8 and this part 9 of the terminal is fastened as by welding to the lead wire arm I. This part 9 of the filament terminal is flattened on one side and the portion of the turns of the filament coil are embedded in the flattened side of the part 9. In the particular embodiment shown the part 9 is flattened on opposite sides to form flat surfaces 19 between which are disposed round surfaces It and Figs. 4 and 5 show the opposite portions of the turns of the coils 5 as embedded in the flattened sides ill of the terminal supporting part 9. The turns of the coils 5 pass around the unfiattened edges H of the supporting part 9 without being embedded therein but thesepor tions of the turns press closely against the rounded edges H as the turns of the coils 5 closely surround the terminal supporting part By embedding the fine filamentary wire of the filament terminal in the terminal supporting part 9 the filament ends are thereby firmly anchored to the terminal supporting part 9 against unravelling or dislodgment and the flattened side or sides it where the filament is embedded afford a line contact with the lead arm T for firmly welding the terminals to the lead wires. As illustrated in Fig. 3 the filament unit and the cathode 2 are preferably assembled with the filament terminal support 6 extending up into the cathode a short distance as, for example, a distance of from 1 to 2 millimeters.

The filamentary unit and cathode assembly have the advantages, among others, of having a rigid terminal supporting and welding part 9 with the filament turns embedded therein so as to prevent any tendency of the filament to become dislodged or removed from the support, and so as to present a solid piece of metal 9 to the lead arm I to which it is to be welded and of having an adjacent and integral supporting terminal part 8 about which the filament turns are closely wound without being embedded therein to form a sort of cushioning section for the heating or body part 5 of the filament. The supporting and mounting terminal part 6 of the filament end may be of any suitable length but we have obtained satisfactory results where this part is around 8 to 9 millimeters and the structure and assembly described render easier and facilitate the mounting of the filament units on the lead wires, and the assembly in the cathode tubes 2, the filament terminal forming a rigid integral aligning support for the filament durin this mounting and assembly operation. Another advantage of this filamentunit is that there is no appreciable tendency for the coating material with which the filament body parts 5 are treated to seep along the terminal 6 to the welding part 9 and there to interfere with the welding and the forming of a good electrical connection with the lead arm I, which often happens in the conventional practice where the filament terminals are not provided with an internal support about which a part of the filament'is closely wound and a part of the filament is embedded, as shown and described above. In the embodiment of Fig. 7 the terminal supporting and mounting part 6 is provided with a slightly elongated reduced in diameter portion or tapered end 8' and with this structure a substantially reduced tube loss is obtained as compared with the conventional practice. It is believed that this reduction in tube loss is due in part to the seepage of coating material on the under sides 4 of the coils of the filament 5 adjacent and along the tapered portion 8' which tends to strengthen the coatings applied to the part of the coil 5 in that region where the filament 5 tends to form bends and in part to the tendency to form a more gradual bend at the tapered or reduced end but We do not desire to be restricted to any theory of functioning in this respect.

The method of manufacturing the

filament elements

5, 6 is diagrammatically illustrated in Figs. 8 to 10. A filamentary wire 15 is closely coiled and wound about a metallic wire core Hi from a wire carrying reel l1 somewhat in the conventional manner of formin coil filaments of less fine wire. This step is illustrated at A, Fig. 8. With the filamentary wire l5 thus wound in closely formed coils and closely about the surface of the wire core or mandrel l6 suitable lengths of this combined filamentary coil and core wire it are severed as indicated at B in Fig. 8. The terminal supports for the filamentary part of the filament are formed out of the'core or mandrel wire I6 and before or after the severing of the lengths 18, either at one or both ends, simultaneously, the ends of the lengths 18 formed or to be formed are flattened and the filamentary wires are embedded in the flat sides of the mandrel thus flattened to form theflat sided welding parts 9 of the terminals. This maybe done on any suitable hand or machine press, omitted for convenience in illustration. In the particular embodiment shown, the. lengths l8 are severed at both ends and then flattened and the wires embedded.

With the ends of the lengths [8 thus flattened, with the filamentary wire l5 at the ends of the lengths embedded in the fiat sides of the flat portion 9 the lengths [8 are subjected to a suitable acid bath to dissolve out the mandrel I9 within the main heating portion 5 of the filament, and the supporting and reinforcing terminals 6 above described are at the same timeformed. In the particular embodiment shown the filament por tion 5 as described above is formed into two substantially parallel branches with the terminals 9 welded to the adjacent lead wire supporting arms I as described above, and the next step D of Fig. 8 is the formation of the lengths 18 into a V [8. With the lengths l8 thus formed the legs of the V are subjected to a suitable acid bath to dissolve out the core wire i6, leaving the heating filament portion 5 without any core, but leaving a flattened portion 9 of the core 'wire and the portions 8, 9' untouched or unaffected by the acid bath. This operation is effected as shown diagrammatically in Fig. 9 by providing any suitable support 20 for a multiple number of the lengths [8' with the support or supports 20 engaging or gripping the flattened ends 9 of the lengths. With the lengths I8 thus supported the support or supports 20 are lowered into an acid bath 2| and the legs of the V lengths l8 are maintained in the bath 2| until the mandrel it of the legs of the V5 is completely dissolved out except for the ends 6 above described consisting of the flattened parts 9 and the part 8.

If it is desired to reduce the diameter of the inner ends of the parts 8 of the'terminals to form the reduced diameter part 8' of Fig. 7, the supports or carriers 20 are first lowered to a depth suificient to form the terminal portions 6 of the desired length by wholly dissolving out the intermediate part of the core wire I6. The supports or carriers 20 are then lowered slightly,

as indicated in dotted lines inFig. 9, to dissolve oif apart. of the periphery of the inner ends ,of

the terminal portions 8 thereof to form an inner supporting. part or parts at the extreme end of the portions 8, which parts are of substantially less diameter than the diameter of the coils of the filament 5. We have roughly indicated in Fig. 7 the generally tapered shape of such extreme end portions8' which preferably extend in the mounted position a short distance into the lower end of the cathode '2, as shown in Fig. '7.

coating material of the conventional practice to insulate the coils of the filament fromeach other and against short circuiting contact with the cathode 2 against the interior of which the filament branches or legs rest for support. may be effected by utilizing the same holder or supports 20 for dipping the V filaments in a catap'horetic bath for coating and accordingly after that portion of the mandrel or core I6 between the terminal supports 6 is dissolved, the holder and the filament are withdrawn and washed and the filaments dipped in the cataphoretic bath, asshown in Fig. 10, the bath being diagrammatically indicated at 22.

The filament units thus completed, the filaments are re'adyfor mounting upon the lead wires l, l and assembly into the cathode 2. The tendency'of' the insulating coating material to seep along the filament terminals and there interfere with the formin of asecure weld and electrical connection with the leads I, 1' is minimized or entirely avoidedby reason of the particular structure of thesupporting terminals 6 wherein the filamentary wire coils are bound about or closely formed about the periphery of the supports with no free'sp'aces '0l.'1 the interior of the coil at the terminals to'induce such seepage. terminals-B are provided with the ends 8' of reduced diameter as compared with the inner This 6 filament coils as, forexample, a hydrogen atmosphere furnace. The core or, mandrel wire l6 may be of anysuitable character so long as the portions intermediate the terminals 6 may be readily dissolved without at the same time impairing the filamentary coil. It may for example be of brass, iron or molybdenum. The

particular acid bath depends on the character of the mandrelorcore I 6 and when molybdenum is used a bath of nitric and sulfuric acid may be used "to dissolve it out. In dissolving the core or mandrel as illustrated in Fig. 9, the level of the bath should be kept fixed so that with a fixed support orholder 29 only the part of the mandrel or core between the terminal supports 6 is affected and ,whilethe temperature of the dissolving bath may vary with dilferent materials I of niandreis or cores, with a molybdenum man- Where the diameter of'the filamentary coils, the coating"- material seeps along the turns of the coils about the reduced portion 8' to form a reinforcement of the coating against chipping at this point where the sharper bends of the non-self-supporting filament arelikely to occur and in the coating step the'filament may be dipped to a point above the tip of the reduced portion 8' of the support, or to a depth coextensive with the length of this reduced 8 form cushioning means between the portions" of the filaments embedded and rigidly fastened to the parts 9 on the one hand, and the heating or body part 5 of the filament. The part 8 also performs an alining function for assisting the operator in assembly with the cathode 2 while the reduced diameter or tapered part 8 of the support imparts the advantages above set forth.

The filament lengths or forms [8' may be cleaned in any conventional manner before dissolving the mandrel or core I6 out of the lengths as, for example, by'subjecting them'to caustic or some other conventional cleaning means,

After such cleaning the filament lengths or forms i8 may be fired at high temperature-to set the drel wehave found that a bath kept at about 40 C is hot enough to give a practical rate of solution. One or more of the steps of our method above described may, if desired, be performed automatically or semi-automatically by machine operations and the method facilitates machine operations. For example, the operations A, B,

'C and DoiFig 8 may, if desired, be wholly auto- In the particular embodiment shown .in Fig. 1 the invention illustrated as, being embodied inthat type of radio tube where:two

heating filament units

5, 6 are connected in series across ordinary house voltage lines from to volts with each heating filament therefor consuming roughly 55to 60 volts, but one of these identical units together with its cathode 2-is omitted from the drawings for convenience in illustration. It is understood, however, that the Jnvention is notlimited to filamentstructures of any particularvoltage limit and an important advantage of. our invention is'that within prac- .tic al limits there is no limit to the fineness of the filamentarywire that can be processed according to this invention to form the highly "improved filamentary units of the above described structure and accordingly the invention is particularly adapted to the production of higher voltage filaments than the 50 odd volts of the filament mentioned above. By the structures and practice above described the loss in waste .or discarded material is minimized and the filament structures have the advantages above set forth. I

For ccnveniencein illustration the coils of the wire lii'ar'e omitted from certain parts of the mandrel [6 as shown in Figs. 8 and 9 and also from certain 'partsof theterminals fi as shown in Figs. 4 and '7, and in these and other figures of. the drawings the spacing of the filam entary and the filamentary turns-'embedded inthe fiattened surfaces.

2.-A cathode heatingfilament assembly for thermionic tubes comprising an elongatedfilamentary coiled'heating element and a hollow 5 cathode into which the coiled filament extends,

said filament having mounting terminals formed of cores disposed in theend sections ofthe coil filament'with the core having across sectional areaapproximating the cross sectional area of 10 the interior of the filament coils with the outer ends of the cores having filament turns embedded in the surfacethereof on one side.

3. A cathode heating filament assembly for thermionic tubes comprising an elongated Illa-- 5 mentary coiled heating element and a hollow cathode into which the coiled filament extends, said filament having mounting terminals formed of cores disposed in the end sections of the coil filament with the core having a cross sectionah area approximating the cross sectional area of the interior of the filament coils and with the outer ends of the cores flattened on two sides and the filamentary turns embedded in the -fiattened surfaces, one end of the hollow cathode'-' projecting down to a point in the vicinity of the inner ends of the cores.

4. A- cathode heating-filament assembly for thermionic tubes comprising an elongated filamentary' coiled heating element and a hollow-3 cathode into which the coiled filament extends,

said filament having-mounting terminals formed of cores disposed in the end sections of the coil Lfilament with the core having a cross sectional area approximatingthe cross sectional area of 313 the interior of the filament coils with the outer ends of the cores having filament turns embedded in the surface thereof on one side, one

end of thehollow cathode projecting down to. a point in the vicinity of the inner ends of the- 2:,-

core.

5. .An elongated non self-supporting coiled filamentary cathode heater for thermionic tubes having One end thereof formed into a mounting terminal with a core disposed therein having a 4 cross sectional area approximating the cross sectional area of the interior of the filamentary coils with the outer end of the core having portions of the filament turns embedded in the surface 'cross sectional area approximating the cross sectional area of the interior of the filamentary coils with the outer end of' the core having portions of the filament turns embedded in the surface thereof and an adjacent portion having the embedded.

7. An elongated non self-supporting coiled filamentary cathode heater for thermionic tubes having one end thereof formed into a mounting terminal with a core disposed therein having a 65 cross sectional area approximatin the cross sectional area of the interior of the filamentary coils with the outer end of the .core flattened on one side and the'filament turns embedded in the flattened surface. 7

8.-A cathode heating filamentassembly comprising an elongated non self-supporting coiled cathode .heating. filamenthaving a core disposed in the end of the coiled filamentand fastened Pa less diameter-dais compared with an adjacent portionthereof anda' hollow cathode into which the-filament :eXtends with' the'inner-end of the core disposed at Lthe entrance. to said hollow cathode. F

9. A cathode'heating filament assembly comprising an elongated coiled filamentary. cathode heating element having, disposed in the end thereofi'a core whose cross sectional area approaches the CIO'SSISSCtiOIlZtI area of the interior of the coilswith certain of the coils rigidly fastened to the core and the inner endAof said core being reduced in diameter .to provide. clearance between the coils and the reduced diameter part and a hollow cathode into-which the filament extends with .the innerrend of .the core. disposed at the entrance tosaid hollow cathode.

' 10. A coiled cathode filamentary heating filamentifor thermionic tubes having a mounting terminal formed of a core disposed in the end ofithe' filament and having across-sectional area approaching in dimensions the cross sectional area of theinterior ofthe coil, said core. being flattened at its outer end with the turns of the filament embedded in the flattened sides thereof and'the inner end of said core being tapered.

.11. A.-coiled, filamentary. electrical. .conductor .having amountingterminal comprising a rigid core disposed within. the-end coils at one end and having a cross sectional areaapproximately equal tothe cross sectional area-of the interior of .the filamentary. coils withtheouter end of the core flattened andthe filamentary conductor embedded in the Iflattened, sides.

'12. A coi1ed,-' filamentary electrical conductor having a .mounting t'erminal comprising a rigid core..disposed within the. end coilsat. .one end .andhaving a cross sectionalarea approximately equal to the.crosssectionaLarea-of the interior of the 'lfilamentary coils with the turns of the coils.at the,outer...end of the corepartially embedded in thesurface .of. .the core.

13.'A coiled,'filamentary electrical non selfsupporting. conductor. having a, mountingterminal comprising-a rigid .coreidisp osed. within the end..coils and havingacross sectional area approximately .equal...to.the cross sectional area of the interior of the filamentary coils with the outer end of the corefiattened and the filamen- 0 tary...wire vembeddeolin the flattened sides.

-14. .A coiled, filamentary, electrical non self- .supporting conductor .having .a mounting ter- -minal comprising a rigid core disposed within the end coilsand havin a cross sectional area 5 approximately equalto the .cross sectional area filament turns closely wound thereabout but not 60 heating element assembly comprising. an elongated filamentary coiled heating element and a hollow cathodel into whichthecoiled filamentextends, said .filament. having mounting terminals .for med-of rcores disposedv in the'end sections of the coilfilament. with :thevcore having a cross sectional area approximating thecross sectional areaof the interior of the filament coils and with the outer ends of the cores flattened on two sides and the filamentary turns embedded in the flattened surfaces. I

16..A cathode-heating filament assembly for thermionic tubes comprising an elongated hollow cathode for the reception of a heating filamentand an elongated filamentary coil heating thereto with the inner end oi the core being of "(5 element disposed in said hollow cathode, said filamentary element being non-self-supporting, said filament having mounting terminals formed of cores disposed in the end sections of the coil filament with the core having a cross-sectional area approximating the cross-sectional area of the interior of the filament coils and with the outer ends of the cores having filament turns which are in part embedded in the surface thereof.

17. A thermionic tube embodying a cathode heating element assembly comprising an elongated non self-supporting coil cathode heating filament having a core disposed in the end of the coil filament and fastened thereto with the inner end of the core being of a less diameter as compared with an adjacent portion thereof and a hollow cathode into which the filament extends with the inner end of the core disposed at the entrance to the hollow cathode.

18. A thermionic tube embodying a cathode heating element assembly comprising an elongated coiled cathode heating filament having a core disposed in the end of the coil filament and fastened thereto with the inner end of the core being of a less diameter as compared with an adjacent portion thereof and a hollow cathode into which the filament extends with the inner end of the core disposed at the entrance to the hollow cathode.

HARRY BENDER.

WILLIAM B. VOORHIS.

REFERENCES CITED The following references are of record in the file of this patent:

Certificate of Correction Patent No. 2,482,826 September 27, 1949 HARRY BENDER ET AL.

It is hereby certified that error appears in the printed specification of the above numbered patent requiring correction as follows:

Column 6, line 68, for the word heated read heating;

and that the said Letters Patent should be read with this correction therein that the same may conform to the record of the case in the Patent Oflice. Signed and sealed this 31st day of January, A. D. 1950.

THOMAS F. MURPHY,

Assistant Commissioner of Patenta.