US1852865A - Carbonized nonemissive electrode - Google Patents
Carbonized nonemissive electrode Download PDFInfo
- Publication number
- US1852865A US1852865A US170063A US17006327A US1852865A US 1852865 A US1852865 A US 1852865A US 170063 A US170063 A US 170063A US 17006327 A US17006327 A US 17006327A US 1852865 A US1852865 A US 1852865A
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- electrode
- electrodes
- carbonized
- tubes
- tube
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J19/00—Details of vacuum tubes of the types covered by group H01J21/00
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J2893/00—Discharge tubes and lamps
- H01J2893/0001—Electrodes and electrode systems suitable for discharge tubes or lamps
- H01J2893/0012—Constructional arrangements
- H01J2893/0019—Chemical composition and manufacture
- H01J2893/0022—Manufacture
- H01J2893/0023—Manufacture carbonising and other surface treatments
Definitions
- My invention relates to electron-discharge devices and particularly to such devices hav--- ing one electrode intended to act as a source of electrons and another electrode not in- 5 tended to become such a source of electrons.
- One object of my invention is to provide means to prevent an electrode intended to be, at all times, non-emissive from acting as a source of electrons even when its temperature is considerably raised or when it is subject to considerable voltage stress.
- Another object of my invention is to provide an electron tube containing thermionicall emissive .oxides' with electrodes having sur aces which destroy the thermionically emissive property of oxides depositing upon them. 4 I
- Another object of my invention is to provide electron tubes'with metal anodes having surfaces having ahigh coeflicient of thermal radiation.
- emissive cathodes particularly cathodes comprising oxides of the alkali-earth metals
- the cathode material to volatilize and deposit upon the anodes or other electrodes of which the intended func- I tion, in operation, is that they shall not emit electrons.
- My process of carbonizing results in a blackening ofthe surface, thereby greatly increasingits ability to radiate heat and, consequently, decreasing the temperature at which it will. operate at a given current.
- a vacuum-tight container 1 has a'press 2 through which inleading wires 3 are sealed, in a manner well known inthe art.
- One of the inleading wires extends parallel to the axis of the tube and is provided with an arm 4 which supports a hot-cathode filament 5 of the well known type comprising a base filament covered with ,a
- the grid electrode 6 Surrounding the grid electrode 6 is a cylindrical plate electrode? which is supported from still others of the aforesaidinleading wires in a manner too well known to r planetary extended description.
- the anode 7, an if desired, the grid electrode 6, are provided with the carbonized coating, which 1s a feature of my invention, in the manner now to be described.
- Electrodes on which I practice my process may be of nickel tungsten, or some other suitable metal. They may be used as main anodes or as control electrodes, or otherwise, wherever an electrode which shall be free from thermionic emission is desired in electron tubes. should, of course, be mechanically clean to begin with. They may be given a preliminary treatment by heating in vacuo for an extended period to free them from-occluded gases.
- the procass of carbonizing the surface consists in heating the electrodes at a temperature of approximately 800 to 1000 C. dependent upon the metal utilized in an atmosphere of acetylene for about 1 to 2 hours in a-furnace from which the air is excluded.
- the electrodes may be annealed by leaving them in the furnace and slowl reducing the tem erature over a period 0 several hours. T ey may thereafter be sealed into containing vessels provided with roper cooperating electrodes as already described in connection with the drawing herein.
- the cathode ma for example, consist of a tungsten or nic el filament coated with a mix: ture of the oxides of barium and strontium.
- Back-emission has been found to be of particularly low value in tubes using a cathode com risin barium and strontium oxides on the ase ament described in a plication Serial No. 144,911 of E. F. Lowry led October 28, 1926 and assi ed to the Westinghouse Electric & M g. Co.
- the electron tubes, produced in accordance with the foregoing, are then subjected to the usual process of exhaust, which has become standardized.-
- the non-emitting electrodes produced by my process may be used as anodes for hot-- cathode rectifiers or may become anode or control electrodes, either or both, in an elec tron tube havin one or more grids.
- anode or control electrodes either or both, in an elec tron tube havin one or more grids.
- the electrodes to be carbonized shielded grid as well as a control grid is greatly improved when electrodes carbonized in accordance with my invention are substitutes for ordinary metallic grids.
- the line voltage on which rectifiers of given dimensions'may be operated can be increased by reason of the absence of danger of thermionic emission from the anodes, with consequent back discharge.
- the cathode temperature and, consequently, the saturation current of the tube may be increased,sincethe consequences of volatilization of the cathode material are much less serious.
- an anode of given dimensions runs at a lower temperature at full load by reason of the increased thermal emissivity of its surface. That, of itself, lessens the danger of the occurence of back discharge, and, furthermore,lessens deterioration of the vacuum of the tube by gases evolved in consequence of the heating of the anode.
- the current and voltage rating of the tube may beincreased in consequence of each of these effects.
- the increased thermal emissivity which results from the blackenin of the metal electrodes is useful, indepen ently of whether cathode material deposits on the anode or not and, furthermore, that it is not limited to carbonization as a process of producing the-blackened surface.
- A. high vacuum electrical dischar e tube comprising a cathode com risin a t ermionically emissive oxide an an e ectrode 00- I Lancet 0 rating therewith comprising a composite 0 carbon and a metal.
- a high vacuum electrical dischar 7 tube comprising a cathode com rising a ermi-- 6 onically 'emissive oxide an a metallic electrode cooperating therewith comprising a a surface layerincluding a composite of carf bonandametal.
- An electrical discharge tube compri's- 1 ing a cathode comprising an oxide of a metal in the alkali-earth group and an electrode cooperating therewith com rising a composite of carbon and a met 4.
- An electrical discharge tube compria- It ing an emissive cathode subject to vaporiza tion and an anode member and a control electrode member each cooperating 'there-' 1 with, said'members comprismg a composite of carbon'and a m so
- An electrical'discha rge tube comprising an emissive cathode su ject'to vaporiza tion and an electrodeeooperahngotillierewith confiiplnsmg' a composite of car me I 86 In testimony whereof, I have, hereunto subscribed my namethis14th day of Febru ary, 1927.” r
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Description
Filed Feb. 21, 1927 UUUU IINVENTOR h a/ /es B A TORNE l PatentedApr. 5, 1932 tmm STATES PATENTfoFFICE CHARLES 18. UPI, 01:.WILKINSBUBG, PENNSYLVANIA, ASSiIGNOB TO WESTINGHOUSE ELECTRIC & MANUFACTURING COMBANY; A CORPORATION OF PENNSYLVANIA v CARBON'IZED NONEMISSIVE ELECTRODE Application flled February 21, 1927. Serial No. 170,063.
- My invention relates to electron-discharge devices and particularly to such devices hav-- ing one electrode intended to act as a source of electrons and another electrode not in- 5 tended to become such a source of electrons.
One object of my invention is to provide means to prevent an electrode intended to be, at all times, non-emissive from acting as a source of electrons even when its temperature is considerably raised or when it is subject to considerable voltage stress.
Another object of my invention is to provide an electron tube containing thermionicall emissive .oxides' with electrodes having sur aces which destroy the thermionically emissive property of oxides depositing upon them. 4 I
Another object of my invention is to provide electron tubes'with metal anodes having surfaces having ahigh coeflicient of thermal radiation.
1 Other objects of my invention will become apparent from the following description.
In electron tubes having thermionically. emissive cathodes, particularly cathodes comprising oxides of the alkali-earth metals, there is a tendency for the cathode material to volatilize and deposit upon the anodes or other electrodes of which the intended func- I tion, in operation, is that they shall not emit electrons.
Since tubes in which the power output is considerable have anodes which run at rather elevated temperatures, the result of. such deposition is that the anodes fail to perform their expected function and become emitters of electrons. In-cases, for example, of diode tubes acting as rectifiers, this results in the 40 short circuiting of the A. C. line, with disastrous consequences.
,I have found that, by treatment of the anodes of such electron tubes to carbonize their surfaces the tendency to become emitters of electrons is practically obviated. Data have been secured which demonstrate that the phenomenon is not capable of ready explanation on the basis of known chemical laws. ,VVhatever may be the cause of the results obt ained, the discovery has proved of great value in improving the voltage and current rating at which electron tubes may be operated.
Another improvement upon electron tubes I of the prior art has resulted from my process of carbonizing the electrodes. The power output of such tubes has been limited, in' the past, by the ability of their anodes to dissipate heat. It is desirable that the electrodes in high-vacuum tubes shall be of metal since metals may be freed from occluded gases to an extent which is impossible, for example, in the case of graphite. Tubes having metallic electrodes can, in. fact, operate at the very high vacuum desired in presentday practice for much longer periods than would be possible with any type of porous electrode,
Metallic electrodes, however,normally have bright surfaces.
My process of carbonizing results in a blackening ofthe surface, thereby greatly increasingits ability to radiate heat and, consequently, decreasing the temperature at which it will. operate at a given current. As
afresult of substitutingmy carbonized electrodes for ordinary metallic electrodes of the same dimensions, the capacity of standard rectifier tubes was found to be increased35%.
With the foregoing principles and objects in mind,'my invention maybe more. readily understood by reference to the accompanying drawing which shows'a three-electrode tube of a usual type in which my invention has been embodied.
Referring to the drawing a vacuum-tight container 1 has a'press 2 through which inleading wires 3 are sealed, in a manner well known inthe art. One of the inleading wires extends parallel to the axis of the tube and is provided with an arm 4 which supports a hot-cathode filament 5 of the well known type comprising a base filament covered with ,a
coating of barium oxide and strontium oxide. Others of the aforesaid inleading wires support a grid electrode 6, which may be formed,
in a manner well known in the art, by winding a helix of molybdenum between vertical support arms. Surrounding the grid electrode 6 is a cylindrical plate electrode? which is supported from still others of the aforesaidinleading wires in a manner too well known to r uire extended description. The anode 7, an if desired, the grid electrode 6, are provided with the carbonized coating, which 1s a feature of my invention, in the manner now to be described.
Electrodes on which I practice my process may be of nickel tungsten, or some other suitable metal. They may be used as main anodes or as control electrodes, or otherwise, wherever an electrode which shall be free from thermionic emission is desired in electron tubes. should, of course, be mechanically clean to begin with. They may be given a preliminary treatment by heating in vacuo for an extended period to free them from-occluded gases.
Having been properly prepared, the procass of carbonizing the surface consists in heating the electrodes at a temperature of approximately 800 to 1000 C. dependent upon the metal utilized in an atmosphere of acetylene for about 1 to 2 hours in a-furnace from which the air is excluded.
While I have found acetylene to be effective as a carbonizing agent, I have also found that illuminating gas may be used with excellent results, and it is my belief that many other gaseous carbon compounds, the identity of which will be evident to skilled chemists, Wlll serve the required purposes.
. As a result of such treatment at high temerature inan acet lene atmosphere, the surace of the electrod c becomes carbonized in a very permanent form, probably by formation of a carbide of the metal. 7
After the completion of the carbonizing treatment, the electrodes may be annealed by leaving them in the furnace and slowl reducing the tem erature over a period 0 several hours. T ey may thereafter be sealed into containing vessels provided with roper cooperating electrodes as already described in connection with the drawing herein. The cathode ma for example, consist of a tungsten or nic el filament coated with a mix: ture of the oxides of barium and strontium. Back-emission has been found to be of particularly low value in tubes using a cathode com risin barium and strontium oxides on the ase ament described in a plication Serial No. 144,911 of E. F. Lowry led October 28, 1926 and assi ed to the Westinghouse Electric & M g. Co. The electron tubes, produced in accordance with the foregoing, are then subjected to the usual process of exhaust, which has become standardized.-
in the art and is too well-known to require extended description here.
The non-emitting electrodes produced by my process may be used as anodes for hot-- cathode rectifiers or may become anode or control electrodes, either or both, in an elec tron tube havin one or more grids. For example, the per ormance of a tube having a The electrodes to be carbonized shielded grid as well as a control grid is greatly improved when electrodes carbonized in accordance with my invention are substitutes for ordinary metallic grids.
By the use of electron tubes provided with my carbonized. electrodes, the line voltage on which rectifiers of given dimensions'may be operated can be increased by reason of the absence of danger of thermionic emission from the anodes, with consequent back discharge.
The cathode temperature and, consequently, the saturation current of the tube may be increased,sincethe consequences of volatilization of the cathode material are much less serious. Simultaneously, an anode of given dimensions runs at a lower temperature at full load by reason of the increased thermal emissivity of its surface. That, of itself, lessens the danger of the occurence of back discharge, and, furthermore,lessens deterioration of the vacuum of the tube by gases evolved in consequence of the heating of the anode. The current and voltage rating of the tube may beincreased in consequence of each of these effects.
In the case of three or four electrode tubes, corresponding advantages are obtained from the decreased tendency of the anode and con 'trol electrodes to thcrmionically emit and also from their increased thermal emissivity conse uent upon the carbonization.
i vhile I have shown one way of carbonizing the various elements of electron tubes, various other methods will be evident to persons of skill in the art, and I desire that my claims, shall not be limited to the precise process which I have described.
It is also obvious that other metals than nickel or tungsten may constitute the inert electrodes and" that other thermionic emitters than barium and strontium oxides may constitute the cathodes.
It is also evident that the increased thermal emissivity which results from the blackenin of the metal electrodes is useful, indepen ently of whether cathode material deposits on the anode or not and, furthermore, that it is not limited to carbonization as a process of producing the-blackened surface.
While, therefore, I have here described my invention in accordance with the patent statutes to illustrate the construction and o eration thereof, it is apparent that various c anges and modifications may be made in.
the precise process I describe without departing from the spirit of my invention. I desire, therefore, that only such limitations shall be imposed thereon as are indicated by the appended claims or demanded by. the prior art.
I claim as my invention 1. A. high vacuum electrical dischar e tube comprising a cathode com risin a t ermionically emissive oxide an an e ectrode 00- I Lancet 0 rating therewith comprising a composite 0 carbon and a metal.
2. A high vacuum electrical dischar 7 tube comprising a cathode com rising a ermi-- 6 onically 'emissive oxide an a metallic electrode cooperating therewith comprising a a surface layerincluding a composite of carf bonandametal.
3. An electrical discharge tube compri's- 1 ing a cathode comprising an oxide of a metal in the alkali-earth group and an electrode cooperating therewith com rising a composite of carbon and a met 4. An electrical discharge tube compria- It ing an emissive cathode subject to vaporiza tion and an anode member and a control electrode member each cooperating 'there-' 1 with, said'members comprismg a composite of carbon'and a m so An electrical'discha rge tube comprising an emissive cathode su ject'to vaporiza tion and an electrodeeooperahngotillierewith confiiplnsmg' a composite of car me I 86 In testimony whereof, I have, hereunto subscribed my namethis14th day of Febru ary, 1927." r
anda Y @cHA LEsnuPP.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US170063A US1852865A (en) | 1927-02-21 | 1927-02-21 | Carbonized nonemissive electrode |
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US170063A US1852865A (en) | 1927-02-21 | 1927-02-21 | Carbonized nonemissive electrode |
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2497111A (en) * | 1947-07-25 | 1950-02-14 | Eitel Mccullough Inc | Electron tube having carburized thoriated cathode |
US2821496A (en) * | 1951-08-03 | 1958-01-28 | Gen Electric | Non-emissive grids |
US2840493A (en) * | 1952-11-22 | 1958-06-24 | Westinghouse Electric Corp | Method of emission suppression in vacuum tubes, especially magnetron hats |
US2890375A (en) * | 1954-11-18 | 1959-06-09 | English Electric Valve Co Ltd | Collector electrodes for klystron tubes |
US2979631A (en) * | 1958-05-14 | 1961-04-11 | Nat Res Corp | Process for the production of ion-emitting surfaces, particularly for halogen leak detectors |
US2992360A (en) * | 1953-05-13 | 1961-07-11 | Csf | Suppressor device for the secondary emission current in magnetic field electronic tubes |
-
1927
- 1927-02-21 US US170063A patent/US1852865A/en not_active Expired - Lifetime
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2497111A (en) * | 1947-07-25 | 1950-02-14 | Eitel Mccullough Inc | Electron tube having carburized thoriated cathode |
US2821496A (en) * | 1951-08-03 | 1958-01-28 | Gen Electric | Non-emissive grids |
US2840493A (en) * | 1952-11-22 | 1958-06-24 | Westinghouse Electric Corp | Method of emission suppression in vacuum tubes, especially magnetron hats |
US2992360A (en) * | 1953-05-13 | 1961-07-11 | Csf | Suppressor device for the secondary emission current in magnetic field electronic tubes |
US2890375A (en) * | 1954-11-18 | 1959-06-09 | English Electric Valve Co Ltd | Collector electrodes for klystron tubes |
US2979631A (en) * | 1958-05-14 | 1961-04-11 | Nat Res Corp | Process for the production of ion-emitting surfaces, particularly for halogen leak detectors |
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