US1374679A - Degasifying process - Google Patents
Degasifying process Download PDFInfo
- Publication number
- US1374679A US1374679A US365837A US36583720A US1374679A US 1374679 A US1374679 A US 1374679A US 365837 A US365837 A US 365837A US 36583720 A US36583720 A US 36583720A US 1374679 A US1374679 A US 1374679A
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- Prior art keywords
- gas
- high frequency
- anode
- envelop
- gases
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J9/00—Apparatus or processes specially adapted for the manufacture, installation, removal, maintenance of electric discharge tubes, discharge lamps, or parts thereof; Recovery of material from discharge tubes or lamps
- H01J9/38—Exhausting, degassing, filling, or cleaning vessels
- H01J9/385—Exhausting vessels
Definitions
- the present invention relates to the removal. of gas from solids and particularly to the removal of gas from conductive bodies 01' electrodes in electrical discharge devices, such for example, as pliotrons, tungar rectifiers, or the like.
- My invention- is of particular utility in the pretreatment of the electrodes in devices of the thermionic type comprising a sealed bulb containing an incandescent cathode and one or more relatively massive unheated electrodes.
- these devices are operated in a high vacuum and in other cases are operated in an atmosphere of some selected gas. In either case it is necessary to pretreat the electrodes to remove gases which otherwise would be driven off during the operation of the device and injuriouslv affect its operation.
- conductive masses are rendered free from gas by subjecting them, preferably in a maintained vacuum, to a magnetic field of sufficiently hig frequency and intensity to heat these bodies to a desired temperature.
- the electron discharge device shown in are sealed conductors leading to a filamentary cathode 4, mounted on a support 5, and an anode 6 consisting, for example, of tungsten, .molybedenum, platinum, or the like-
- the anode 6 is mounted upon a support 7 which is sealed into the container.
- a grid 8 is located between the anode and the cathode whereby the electron current in thedeviee may be controlled.
- this device commonly known as a pliotron, is well 66 known and is here shown as illustrative of a class of devices which maybe advantageously treated in accordance with my invention, the structural features of the dcvice need not be described in greater detail. 70
- conductive parts within the bulb 3 and particularly the anode are heated by a magnetic field induced by a winding 9, which may he slipped over the device in any convenient way.
- the winding 9 is connected to a source of high frequency current (not shown) by the conductor 10, 11.
- The-pliotron preferably is glven the usual preliminary bake-out to remove water vapor before being placed in the high frequency field.
- the envelop Before or during the application of the field the envelop is exhausted to a low pressure by a suitable vacuum pump (not shown) through a tubulature 12.
- a suitable vacuum pump not shown
- the device to be exhausted is not subjected to the high frequency field until the residual gas pressure in the envelop 3 is as low as a few microns, or even lower.
- the high frequency current induced in the anode 6 should be sufficient to heat the anode to bright redness and envelop gas occluded therein.
- the pump is continued in operation during this heat treatment to remove gases evolved from the anode. This degasifying treatment is continued until no more gases are evolved. In many cases, the deleterious gases are effectually removed in a few minutes. In other cases, the high frequency field may be applied advantageously for half an hour, or even longer.
- the device shown in Fig. 2 is adapted for operation with an arc-like discharge in suitable gases, such, for example as nitrogen,
- the tungar rectifier A form now in general use in installations for charging batteries is known as the tungar rectifier.
- the bulb 13 likewise is connected to a pump (not shown) by a tube 12
- the anode 14 in this case usually consists Pref- 8 of graphite, but may consist of various other conductive materials.
- the bulb is baked out and exhausted in the usual manner, and when the residual gas pressure has been reduced to a low value, say, a few microns or less, the anode and other conductive bodies within the bulb are heated by a high frequency magnetic field, pumping being continued asdescribed in connection with Fig. 1. After substantially all occluded gases have been removed, the high frequency-coil is removed and a desired gaseous filling is introduced into the bulb 13. which is finally sealed.
- My invention is applicable not only to thetreatment of electrodes in vacuum tubes, but is equally apphcableto heat any conductive body in an envelop rendering the usual methods of heating difiicult or impossible. It
Description
J. B. PRATT;
DEGASIFYING PROCESS.
APPLICATION FILED MAR- I5. I920.
1,374, 79. Patented A pr.12,1921.
Inventor- John B. Pratt, v
His Attorney.
unm-
UNITED STATES IPA'IENT' OFFICE;
JOHN B. PRATT, OF
SCHENECTADY, NEW YORK, ASSIGNOR TO GENERAL ELECTRIC COMIANY, A CORPORATION OF NEW YORK.
' nnoasrrvme rnoonss.
Specification of Letters Patent. Patented A 12 1921 Application filed March 15, 1920. Serial'No. 365,837.
To all whom it may concern Be it known that I, JOHN B. PRATT, a
citizen of the United States, residing at Schenectady, in the county of Schenectady, State of New. York, have invented certain new and useful Improvements in Dcga'sifying Processes, of which the following is a specification.
The present invention relates to the removal. of gas from solids and particularly to the removal of gas from conductive bodies 01' electrodes in electrical discharge devices, such for example, as pliotrons, tungar rectifiers, or the like.
My invention-is of particular utility in the pretreatment of the electrodes in devices of the thermionic type comprising a sealed bulb containing an incandescent cathode and one or more relatively massive unheated electrodes. In some cases these devices are operated in a high vacuum and in other cases are operated in an atmosphere of some selected gas. In either case it is necessary to pretreat the electrodes to remove gases which otherwise would be driven off during the operation of the device and injuriouslv affect its operation.
In many cases it is possible during the manufacture of the device, to drive gases out of electrode masses by the heating effect of an operating current derived fror' an incandescent cathode, but even when this is possible the cathode is liable to be injured by sputtering and in fact the entire device is in danger of destruction by arcing due to ionization of the gases before they can be removed-by a pump. In some cases such preliminary treatment of the electrodes during evacuation is not effective and may not e possible because of some peculiar structural features of the device.
In accordance with my invention, conductive masses are rendered free from gas by subjecting them, preferably in a maintained vacuum, to a magnetic field of sufficiently hig frequency and intensity to heat these bodies to a desired temperature.
I have shown diagrammatically in the accompanying drawing a high frequency induction heater applied to Figure 1 to the preparation of a vacuum tube, and in Fig.
2 .to the preparation of a gas-filled are device.
The electron discharge device shown in are sealed conductors leading to a filamentary cathode 4, mounted on a support 5, and an anode 6 consisting, for example, of tungsten, .molybedenum, platinum, or the like- The anode 6 is mounted upon a support 7 which is sealed into the container. A grid 8 is located between the anode and the cathode whereby the electron current in thedeviee may be controlled. As this device, commonly known as a pliotron, is well 66 known and is here shown as illustrative of a class of devices which maybe advantageously treated in accordance with my invention, the structural features of the dcvice need not be described in greater detail. 70
a In accordance with my invention, conductive parts within the bulb 3 and particularly the anode, are heated by a magnetic field induced by a winding 9, which may he slipped over the device in any convenient way. The winding 9 is connected to a source of high frequency current (not shown) by the conductor 10, 11.
The-pliotron preferably is glven the usual preliminary bake-out to remove water vapor before being placed in the high frequency field. Before or during the application of the field the envelop is exhausted to a low pressure by a suitable vacuum pump (not shown) through a tubulature 12. erably the device to be exhausted is not subjected to the high frequency field until the residual gas pressure in the envelop 3 is as low as a few microns, or even lower.
The high frequency current induced in the anode 6 should be sufficient to heat the anode to bright redness and envelop gas occluded therein. The pump is continued in operation during this heat treatment to remove gases evolved from the anode. This degasifying treatment is continued until no more gases are evolved. In many cases, the deleterious gases are effectually removed in a few minutes. In other cases, the high frequency field may be applied advantageously for half an hour, or even longer.
The device shown in Fig. 2 is adapted for operation with an arc-like discharge in suitable gases, such, for example as nitrogen,
argon, hydrogen, mercury vapor, or the like. we
A form now in general use in installations for charging batteries is known as the tungar rectifier. The bulb 13 likewise is connected to a pump (not shown) by a tube 12 The anode 14: in this case usually consists Pref- 8 of graphite, but may consist of various other conductive materials.
The bulb is baked out and exhausted in the usual manner, and when the residual gas pressure has been reduced to a low value, say, a few microns or less, the anode and other conductive bodies within the bulb are heated by a high frequency magnetic field, pumping being continued asdescribed in connection with Fig. 1. After substantially all occluded gases have been removed, the high frequency-coil is removed and a desired gaseous filling is introduced into the bulb 13. which is finally sealed.
My invention is applicable not only to thetreatment of electrodes in vacuum tubes, but is equally apphcableto heat any conductive body in an envelop rendering the usual methods of heating difiicult or impossible. It
is important in many cases to prevent the slow evolution of gas from conductive parts in vacuum tubes which are not ordinarily traversed by enough electric current to heat them to a high temperature. In other cases,
, it may be desired to heat or even to vaporize metal not connected in any way to an electric circuit but sea-led within an envelop.
This may readily be done by my improved method.
' What I claim as new and desire to secure by Letters Patent of the United States, is
1. The method of removing gas from electrically conducting masses which consists in materially reducing the gaseous pressure in the environment of said masses and heating sa-id masses to an elevated temperature by electric induction at sufficiently high frequency to make interlinkage with a magnetic core unnecessary.
2. The method of removing gas from conducting bodies inclosed Within an envelop which consists in subjecting said bodies to a high frequency variable magnetic field of sufficient strength to heat said bodies; sufficiently to eliminate said gas.
3. The method of preparing electric discharge devices having conductingbodies inelosed within an envelop which. consists in heating said bodies by a high frequency magnetic field to remove gas therefrom, removing said gas from said envelop and sealing said envelop. E
4. The methods-of preparing thermionic devices to bevop'e-rable with a substantially pure electron discharge which consists in evacuating said devices at an elevated temperature, heating conductive masses in said device, such as an anode, to a high temperature with a high frequency magnetic field while continuing the evacuation to :remove gas evolved from said'masses,'and sealing said devices while highly evacuated;
In witness whereof have hereunto set my hand this 12th day of March, 1920.
JNO. B. PRATT.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US365837A US1374679A (en) | 1920-03-15 | 1920-03-15 | Degasifying process |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US365837A US1374679A (en) | 1920-03-15 | 1920-03-15 | Degasifying process |
Publications (1)
Publication Number | Publication Date |
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US1374679A true US1374679A (en) | 1921-04-12 |
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US365837A Expired - Lifetime US1374679A (en) | 1920-03-15 | 1920-03-15 | Degasifying process |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2458012A (en) * | 1946-04-03 | 1949-01-04 | Westinghouse Electric Corp | Apparatus for high frequency dielectric heating of condenser bushings |
US2701175A (en) * | 1950-12-29 | 1955-02-01 | Texas Co | Method for treating gamma ray detectors |
US2935395A (en) * | 1955-02-21 | 1960-05-03 | Stauffer Chemical Co | High vacuum metallurgical apparatus and method |
-
1920
- 1920-03-15 US US365837A patent/US1374679A/en not_active Expired - Lifetime
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2458012A (en) * | 1946-04-03 | 1949-01-04 | Westinghouse Electric Corp | Apparatus for high frequency dielectric heating of condenser bushings |
US2701175A (en) * | 1950-12-29 | 1955-02-01 | Texas Co | Method for treating gamma ray detectors |
US2935395A (en) * | 1955-02-21 | 1960-05-03 | Stauffer Chemical Co | High vacuum metallurgical apparatus and method |
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