US2075855A - Magnetron - Google Patents
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- US2075855A US2075855A US66379A US6637936A US2075855A US 2075855 A US2075855 A US 2075855A US 66379 A US66379 A US 66379A US 6637936 A US6637936 A US 6637936A US 2075855 A US2075855 A US 2075855A
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- legs
- magnetron
- anode
- envelope
- tube
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J25/00—Transit-time tubes, e.g. klystrons, travelling-wave tubes, magnetrons
- H01J25/50—Magnetrons, i.e. tubes with a magnet system producing an H-field crossing the E-field
- H01J25/52—Magnetrons, i.e. tubes with a magnet system producing an H-field crossing the E-field with an electron space having a shape that does not prevent any electron from moving completely around the cathode or guide electrode
Definitions
- My invention relates to electron discharge devices for use at high frequencies, more particularly to improvements in devices of the so-called magnetron type in which the electrode system is 5 positioned within a magnetic field.
- the conventional magnetron comprises a straight thermionic cathode, usually in the form of a filament, an anode coaxial with and surrounding the thermionic cathode and a magnet 1() for producing a strong magnetic field parallel to the cathode.
- the anode which may be of the multi-segment type, is usually the so-called split anode with two semi-cylindrical sections.
- the magnetron tube is particularly useful at 5 very high frequencies, that is, frequencies of the order of 300 megacycles and higher. In order to function at these high frequencies the tubes must have very small electrodes. It is difiicult to provide for such tubes an external circuit which will 0 have inductance and capacity low enough to respond to the higher frequencies at which the tube can operate.
- One partial solution of this prob lem is to use internal circuit magnetrons, in which the oscillator circuit comprises a loop of wire inside the tube envelope and connected directly to the electrode system. Such a magnetron and its associated circuit will function at high frequencies, but the power output is limited to only a few watts by the heat generated during operation of the tube. Blackening or roughening the surface,
- the anode increases the heat dissipation of a tube, but is of little practical effect with small anodes, and also increases the high frequency resistance of the anode because substantially all of the high frequency currents flow on the surface.
- Another difficulty encountered in magnetron tubes with glass envelopes is the softening of the glass near the ends of the anode and cathode due to the concentration of the electrons on the glass envelope at these points.
- object of my invention is to provide such a high power magnetron in which the softening of the glass envelope adjacent the ends of the oathode and anode is eliminated.
- FIG. 1 is a v perspective view with parts broken away of an electron discharge device of the magnetron type embodying my invention
- Figure 2 is an enlarged longitudinal section of the upper part of Figure 1
- Figure 3 is a transverse section taken along the line 3-3 of Figure 2
- Figures 4, 5 and. 6 show modifications of my invention.
- the preferred embodiment of my invention is a magnetron of the split anode type which comprises an evacuated envelope [0 provided with a conventional base II and press l2.
- the electrode assembly is supported on the press by a pair of lead and support wires i3.
- the electrode assembly is provided with a directly connected internal circuit and comprises a U-shaped member I 4, preferably of copper, having semicylindrical legs I5 having a large heat absorbing capacity, the inside facing surfaces of which are flat and parallel.
- the heat radiation of these legs is increased by a black coating [6, preferably carbon, on only their outside surfaces, as shown in the drawing.
- Preferably no coating is applied along the margin ll adjacent the inside sur faces of the legs IS.
- the lower free ends of the U- shaped member M are provided with inwardly extending portions l8 having oppositely disposed semi-cylindrical surfaces providing a central circular bore 19. These two extensions constitute the anode segments of the split anode magnetron.
- the U-shaped portion constitutes the internal circuit directly connected to the two segments of the anode.
- the legs of the U-shaped member can be considered as elongated parallel extensions of the anode segments and as electrically connected at the ends remote from the anode segments to provide an internal circuit.
- a straight thermionic cathode 20, preferably a heavy filament, is supported axially of the central bore or cylindrical chamber [9 on the leads [3, as best shown in Figure 2.
- also supported on and electrically connected to the leads I3 adjacent the anode at the opposite ends of the oathode, shield the glass envelope [0 from the electrons which would otherwise be concentrated on it.
- These shields are preferably of non-magnetic metal, such as molybdenum, so as not to interfere with the magnetic field which is induced parallel to the cathode during operation of the tube.
- a support comprising a heavy wire or rod 22 and a smaller wire 23 fused into a member 24 of glass or ceramic material carried on the lead wires [3.
- the wires 23 may be connected to pins in the base to serve as a connection to external transmission lines, or they may terminate as shown in Figure 2, just below the mica spacer 21. Other methods may then be employed to couple the internal circuit to the transmission lines.
- the U-shaped member I4 is o electrically connected at the top to a flexible lead 25 to provide a voltage connection for the anodes at the lower end of the U-shaped member M. This flexible lead also allows expansion and con traction of the electrodes during operation of the i tube.
- the bottom lead i3 could be made flexible instead of the top lead 25.
- the mount is spaced from the walls of the tube envelope at the upper end by the mica spacer 26 secured to the U-shaped member l4 and at the lower end by the mica spacer 2!
- Electro-magnets 28 positioned at opposite ends of the cathode on the outside of the envelope provide a strong magnetic field longitudinal of the cathode during operation of the tube.
- the conventional internal circuit member used with a magnetron comprises a wire loop connected to the anode segments.
- the heat dissipation by as well as heat conduction from the anodes is very limited inasmuch as the anode surfaces are of small area and the internal wire loop is of small cross section as well as small area. Blackening the surfaces of the anode segments is in- 00 effective because the surfaces are too small to ra-- diate and thus dissipate much heat. Roughening or blackening the wire loop of the internal circuit member is objectionable because the resistance of the wire surfaces to high frequency current which flow mainly on and near the surfaces of the conductors is increased, thus increasing the power losses in the magnetron. I have solved both the problem of heat conduction from the anode segments and heat dissipation to increase 0 the power output of a magnetron by my invention, at the same time decreasing the resistance to the flow of high frequency currents.
- the legs [5 of the U-shaped member l4 have a large area and transverse cross section, one of their dimensions being preferably as great as the anode segments themselves. These legs have a large mass in comparison with the anode segments. As heat developed at the internal surfaces of the anode segments is quickly conducted away and dissipated by the legs I5, the anode segments are kept comparatively cool. While the legs naturally dissipate heat by radiation, I make them much more efficient radiators by roughening and coating them with carbon. While this roughening and coating with carbon increases the emissivity of the internal circuit portion of the magnetron, it increases the high frequency resistance at its surface to the flow of high frequency currents and in the ordinary loop type of circuit would reduce the maximum output of the tube.
- I provide a large conducting surface of comparatively low high frequency resistance for the high frequency currents by forming the legs 55 with large flat parallel surfaces of a width corresponding to the length of the anode segments. In this way the resistance of the internal circuit is reduced and the current density is decreased over that in the conventional loop wire so that the generated heat is decreased. These inside surfaces and a slight margin on the outside of the legs near these flat surfaces are not coated with carbon. At the same time I obtain the advantage of being able to rapidly conduct the heat away from the surfaces carrying the high frequency currents and dissipate it through the envelope of the tube.
- a magnetron tube in accordance with my invention I have been able to increase the output of the tube to from a few watts output, which is the output of the conventional magnetron, to 50 watts output at a wave length of 60 centimeters with an emciency greater than thirty percent.
- the shields iii are effective in preventing the elec trons which pass the ends of the anode from bombarding the glass. This bombardment is particularly bad in magnetrons because of the focusing effect of the magnetic field.
- a magnetron made in accordance with my invention is: a decrease in resistance, increased heat conduction from the tube elements, increased radiating surface, a reduction of dielectric losses and a circuit which will tune to higher frequencies than theexternal circuit type of magnetron. While shown as applied to a magnetron, my invention is equally applicable to other types of tubes in which it is desired to have a large power output at high frequencies.
- Figure 4 I show modified form of magnetron made in accordance with my invention in which the upper end of the envelope has been replaced by a metal cup-shaped member 30 secured to the internal circuit element [4, for example, by welding, and fused to the glass envelope ID to provide an envelope for the tube elements.
- the cup-shaped member 30 could be made integral with the member Id.
- the member 30 can be used as the connecting element and also acts as an external heat radiator for the end of the internal circuit element (4.
- a metal tubular member 32 closed at one end is secured to the circuit element M by a screw member 33, the lip of the tubular member 32 being sealed to the glass envelope If! to close the end of the envelope.
- a water cooling jacket 34 is secured to the member 33 and is provided with an in-take 35 and an exhaust 36. The heat is both radiated from the surface of the legs 15 to the walls of the tubular member 32 as well as conducted to the metallic member 32 through the ends of the circuit element M. This heat of course is absorbed and carried out by the cooling fluid passed through the water jacket 34.
- the internal circuit is connected to the transmission lines by means of the anode leads 23.
- Figure 6 I show a modification of the electron shield for the glass envelope.
- This modification comprises a cylindrical member 35 supported against the glass wall of the envelope It]. It may be coated on the wall of the envelope.
- a magnetron made in accordance with my invention is simple and effective and capable of large power outputs due to the novel construction of the anodes and internal circuit member. While I have shown the anodes and internal circuit member as formed from a copper cylinder, it is apparent that the anodes and the internal circuit member could be made in various other ways; for example, by forming the anodes and legs separately and securing them together and properly spacing them by means of another member at the ends of the legs opposite from the ends carrying the anode segments.
- a magnetron having an envelope containing an elongated U-shaped member, the legs of which have a comparatively large transverse cross section and are of comparatively large mass, the inner facing surfaces of said legs being closely spaced, fiat and parallel, a pair of anode segments at the free ends of said legs on the inside surfaces thereof and having oppositelydisposed semi-cylindrical surfaces providing a cylindrical chamber the axis of which is parallel to the flat surfaces of the legs of said U-shaped member, a straight thermionic cathode positioned axially of said cylindrical chamber and means for inducing a magnetic field longitudinally of said cathode.
- a magnetron having an envelope containing a pair of anode segments having oppositely disposed semi-cylindrical surfaces forming a cylindrical chamber, each of said anodes being provided with an elongated extension, said extensions being parallel and electrically connected at the ends remote from said anodes to provide a U-shaped internal circuit connected to said anode segments, the facing surfaces of the extensions opposed to each other being fiat and parallel and of a width co-extensive with the length of said anodes, said extensions having comparatively thick transverse cross sections in comparison with said anodes, a straight thermionic cathode disposed axially of said anode segments and means for inducing a magnetic field longitudinally of said cathode.
- a magnetron having a tubular envelope containing a longitudinally extending U-shaped member, the legs of which have a comparatively large transverse cross section of semi-cylindrical form, the facing surfaces of the legs being fiat and parallel, anode extensions at the free end of said legs on the facing surface thereof provided with oppositely disposed semi-cylindrical surfaces forming a cylindrical chamber extending parallel to and co-extensive with the fiat surfaces of said legs, a blackened coating on the semi-cylindrical surfaces of said legs to increase the heat emissivity of said legs, a straight thermionic cathode positioned axially of the cylindrical chamber and means for producing a magnetic field longitudinally of said cathode.
- a magnetron having a tubular envelope containing a longitudinally extending U-shaped member, the legs of which have a comparatively large transverse cross section of semi-cylindrical form, the inner facing surfaces of the legs being flat and parallel, the anode extensions at the free ends of said legs on the inside surface thereof provided with oppositely disposed semicylindrical surfaces forming a cylindrical chamber extending parallel to and co-extensive with the flat surfaces of said legs, a blackened coating on the semi-cylindrical surfaces of said legs to increase the heat emissivity of said legs, a straight thermionic cathode positioned axially of said cylindrical chamber, means for producing a magnetic field longitudinally of said cathode, and non-magnetic shields positioned between the ends of the anode segments and the envelope of the tube at opposite ends of said straight thermionic cathode.
- a magnetron having an elongated envelope closed at one end with a tubular metal member and containing an elongated U-shaped member, the legs of which have a comparatively large transverse cross section and are of comparatively large mass, the inner facing surfaces of said legs being closely spaced, flat and parallel, a pair of anode segments at the free end of said legs on the inside surfaces and having oppositely disposed semi-cylindrical surfaces providing a cylindrical chamber, the axis of which is parallel to the fiat surfaces of the legs of said U-shaped member, a straight thermionic cathode positioned axially of said cylindrical chamber and means for producing a magnetic field longitudinally of said cathode, the end of said U-shaped member opposite from said anode segments being Within and secured to said tubular metal member, and a cooling jacket surrounding said tubular metal member.
Description
April 1937- G. R. KILGQRE 2,075,855
MAGNETRON Filed Feb. 29, 1936 2 Sheets-Sheet l NVENTOR 6 GE R. KILGORE ATTORNEY April 6, 1937. G. R. KILGORE MAGNETRON Filed Feb. 29, 1936 2 Sheets-Sheet 2 INVENTOR GEORGE R.| !LGORE w ATTORNEY Patented Apr. 6, 1937 UNITED STATES PATENT OFFICE mesne assignments, America, New York, Delaware to Radio Corporation of N. Y., a corporation of Application February 29, 1936, Serial No. 66,379
Claims.
My invention relates to electron discharge devices for use at high frequencies, more particularly to improvements in devices of the so-called magnetron type in which the electrode system is 5 positioned within a magnetic field.
The conventional magnetron comprises a straight thermionic cathode, usually in the form of a filament, an anode coaxial with and surrounding the thermionic cathode and a magnet 1() for producing a strong magnetic field parallel to the cathode. The anode, which may be of the multi-segment type, is usually the so-called split anode with two semi-cylindrical sections.
The magnetron tube is particularly useful at 5 very high frequencies, that is, frequencies of the order of 300 megacycles and higher. In order to function at these high frequencies the tubes must have very small electrodes. It is difiicult to provide for such tubes an external circuit which will 0 have inductance and capacity low enough to respond to the higher frequencies at which the tube can operate. One partial solution of this prob lem is to use internal circuit magnetrons, in which the oscillator circuit comprises a loop of wire inside the tube envelope and connected directly to the electrode system. Such a magnetron and its associated circuit will function at high frequencies, but the power output is limited to only a few watts by the heat generated during operation of the tube. Blackening or roughening the surface,
for example, of the anode increases the heat dissipation of a tube, but is of little practical effect with small anodes, and also increases the high frequency resistance of the anode because substantially all of the high frequency currents flow on the surface. Another difficulty encountered in magnetron tubes with glass envelopes is the softening of the glass near the ends of the anode and cathode due to the concentration of the electrons on the glass envelope at these points.
It is an object of my invention to provide an improved electron discharge device of the magnetron type operable at ultra-high frequencies and having a comparatively high power output. An-
other object of my invention is to provide such a high power magnetron in which the softening of the glass envelope adjacent the ends of the oathode and anode is eliminated.
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 drawings in which Figure 1 is a v perspective view with parts broken away of an electron discharge device of the magnetron type embodying my invention; Figure 2 is an enlarged longitudinal section of the upper part of Figure 1; Figure 3 is a transverse section taken along the line 3-3 of Figure 2; Figures 4, 5 and. 6 show modifications of my invention.
The preferred embodiment of my invention, shown in Figures 1, 2 and 3, is a magnetron of the split anode type which comprises an evacuated envelope [0 provided with a conventional base II and press l2. The electrode assembly is supported on the press by a pair of lead and support wires i3. In accordance with my invention the electrode assembly is provided with a directly connected internal circuit and comprises a U-shaped member I 4, preferably of copper, having semicylindrical legs I5 having a large heat absorbing capacity, the inside facing surfaces of which are flat and parallel. The heat radiation of these legs is increased by a black coating [6, preferably carbon, on only their outside surfaces, as shown in the drawing. Preferably no coating is applied along the margin ll adjacent the inside sur faces of the legs IS. The lower free ends of the U- shaped member M are provided with inwardly extending portions l8 having oppositely disposed semi-cylindrical surfaces providing a central circular bore 19. These two extensions constitute the anode segments of the split anode magnetron. The U-shaped portion constitutes the internal circuit directly connected to the two segments of the anode. The legs of the U-shaped member can be considered as elongated parallel extensions of the anode segments and as electrically connected at the ends remote from the anode segments to provide an internal circuit. A straight thermionic cathode 20, preferably a heavy filament, is supported axially of the central bore or cylindrical chamber [9 on the leads [3, as best shown in Figure 2. A pair of shields 2|, also supported on and electrically connected to the leads I3 adjacent the anode at the opposite ends of the oathode, shield the glass envelope [0 from the electrons which would otherwise be concentrated on it. These shields are preferably of non-magnetic metal, such as molybdenum, so as not to interfere with the magnetic field which is induced parallel to the cathode during operation of the tube. On each of the lower free ends of the legs l5 of the U-shaped member [4 is a support comprising a heavy wire or rod 22 and a smaller wire 23 fused into a member 24 of glass or ceramic material carried on the lead wires [3. The wires 23 may be connected to pins in the base to serve as a connection to external transmission lines, or they may terminate as shown in Figure 2, just below the mica spacer 21. Other methods may then be employed to couple the internal circuit to the transmission lines. The U-shaped member I4 is o electrically connected at the top to a flexible lead 25 to provide a voltage connection for the anodes at the lower end of the U-shaped member M. This flexible lead also allows expansion and con traction of the electrodes during operation of the i tube. The bottom lead i3 could be made flexible instead of the top lead 25. The mount is spaced from the walls of the tube envelope at the upper end by the mica spacer 26 secured to the U-shaped member l4 and at the lower end by the mica spacer 2! supported on the lead and support wires E3, the edges of the spacers contacting the wall of the envelope of the tube. Electro-magnets 28 positioned at opposite ends of the cathode on the outside of the envelope provide a strong magnetic field longitudinal of the cathode during operation of the tube.
The conventional internal circuit member used with a magnetron comprises a wire loop connected to the anode segments. The heat dissipation by as well as heat conduction from the anodes is very limited inasmuch as the anode surfaces are of small area and the internal wire loop is of small cross section as well as small area. Blackening the surfaces of the anode segments is in- 00 effective because the surfaces are too small to ra-- diate and thus dissipate much heat. Roughening or blackening the wire loop of the internal circuit member is objectionable because the resistance of the wire surfaces to high frequency current which flow mainly on and near the surfaces of the conductors is increased, thus increasing the power losses in the magnetron. I have solved both the problem of heat conduction from the anode segments and heat dissipation to increase 0 the power output of a magnetron by my invention, at the same time decreasing the resistance to the flow of high frequency currents.
The legs [5 of the U-shaped member l4 have a large area and transverse cross section, one of their dimensions being preferably as great as the anode segments themselves. These legs have a large mass in comparison with the anode segments. As heat developed at the internal surfaces of the anode segments is quickly conducted away and dissipated by the legs I5, the anode segments are kept comparatively cool. While the legs naturally dissipate heat by radiation, I make them much more efficient radiators by roughening and coating them with carbon. While this roughening and coating with carbon increases the emissivity of the internal circuit portion of the magnetron, it increases the high frequency resistance at its surface to the flow of high frequency currents and in the ordinary loop type of circuit would reduce the maximum output of the tube. In accordance with my invention I provide a large conducting surface of comparatively low high frequency resistance for the high frequency currents by forming the legs 55 with large flat parallel surfaces of a width corresponding to the length of the anode segments. In this way the resistance of the internal circuit is reduced and the current density is decreased over that in the conventional loop wire so that the generated heat is decreased. These inside surfaces and a slight margin on the outside of the legs near these flat surfaces are not coated with carbon. At the same time I obtain the advantage of being able to rapidly conduct the heat away from the surfaces carrying the high frequency currents and dissipate it through the envelope of the tube. By making a magnetron tube in accordance with my invention I have been able to increase the output of the tube to from a few watts output, which is the output of the conventional magnetron, to 50 watts output at a wave length of 60 centimeters with an emciency greater than thirty percent. The shields iii are effective in preventing the elec trons which pass the ends of the anode from bombarding the glass. This bombardment is particularly bad in magnetrons because of the focusing effect of the magnetic field.
The principal advantages of a magnetron made in accordance with my invention are: a decrease in resistance, increased heat conduction from the tube elements, increased radiating surface, a reduction of dielectric losses and a circuit which will tune to higher frequencies than theexternal circuit type of magnetron. While shown as applied to a magnetron, my invention is equally applicable to other types of tubes in which it is desired to have a large power output at high frequencies.
In Figure 4 I show modified form of magnetron made in accordance with my invention in which the upper end of the envelope has been replaced by a metal cup-shaped member 30 secured to the internal circuit element [4, for example, by welding, and fused to the glass envelope ID to provide an envelope for the tube elements. The cup-shaped member 30 could be made integral with the member Id. The member 30 can be used as the connecting element and also acts as an external heat radiator for the end of the internal circuit element (4.
In the past water cooling of the anode of a magnetron has not been feasible due to the small size of the anode or anode segments and the complications introduced by sealing the intake and exhaust tubes of the cooling system in the glass envelope which construction introduces stresses in the glass envelope at the seals due to temperature differentials of the cooling medium and glass envelope. My invention has made it possible to overcome these difficulties and use water cooling to advantage.
In the modification shown in Figure 5 a metal tubular member 32 closed at one end is secured to the circuit element M by a screw member 33, the lip of the tubular member 32 being sealed to the glass envelope If! to close the end of the envelope. A water cooling jacket 34 is secured to the member 33 and is provided with an in-take 35 and an exhaust 36. The heat is both radiated from the surface of the legs 15 to the walls of the tubular member 32 as well as conducted to the metallic member 32 through the ends of the circuit element M. This heat of course is absorbed and carried out by the cooling fluid passed through the water jacket 34. In this modification the internal circuit is connected to the transmission lines by means of the anode leads 23.
In Figure 6 I show a modification of the electron shield for the glass envelope. This modification comprises a cylindrical member 35 supported against the glass wall of the envelope It]. It may be coated on the wall of the envelope.
' A magnetron made in accordance with my invention is simple and effective and capable of large power outputs due to the novel construction of the anodes and internal circuit member. While I have shown the anodes and internal circuit member as formed from a copper cylinder, it is apparent that the anodes and the internal circuit member could be made in various other ways; for example, by forming the anodes and legs separately and securing them together and properly spacing them by means of another member at the ends of the legs opposite from the ends carrying the anode segments.
While I have indicated the preferred embodiment of my invention of which I am now aware and have also indicated only one specific application for which my invention may be employed, it will be apparent that my invention 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 invention as set forth in the appended claims.
What I claim as new is:
1. A magnetron having an envelope containing an elongated U-shaped member, the legs of which have a comparatively large transverse cross section and are of comparatively large mass, the inner facing surfaces of said legs being closely spaced, fiat and parallel, a pair of anode segments at the free ends of said legs on the inside surfaces thereof and having oppositelydisposed semi-cylindrical surfaces providing a cylindrical chamber the axis of which is parallel to the flat surfaces of the legs of said U-shaped member, a straight thermionic cathode positioned axially of said cylindrical chamber and means for inducing a magnetic field longitudinally of said cathode.
2. A magnetron having an envelope containing a pair of anode segments having oppositely disposed semi-cylindrical surfaces forming a cylindrical chamber, each of said anodes being provided with an elongated extension, said extensions being parallel and electrically connected at the ends remote from said anodes to provide a U-shaped internal circuit connected to said anode segments, the facing surfaces of the extensions opposed to each other being fiat and parallel and of a width co-extensive with the length of said anodes, said extensions having comparatively thick transverse cross sections in comparison with said anodes, a straight thermionic cathode disposed axially of said anode segments and means for inducing a magnetic field longitudinally of said cathode.
3. A magnetron having a tubular envelope containing a longitudinally extending U-shaped member, the legs of which have a comparatively large transverse cross section of semi-cylindrical form, the facing surfaces of the legs being fiat and parallel, anode extensions at the free end of said legs on the facing surface thereof provided with oppositely disposed semi-cylindrical surfaces forming a cylindrical chamber extending parallel to and co-extensive with the fiat surfaces of said legs, a blackened coating on the semi-cylindrical surfaces of said legs to increase the heat emissivity of said legs, a straight thermionic cathode positioned axially of the cylindrical chamber and means for producing a magnetic field longitudinally of said cathode.
4. A magnetron having a tubular envelope containing a longitudinally extending U-shaped member, the legs of which have a comparatively large transverse cross section of semi-cylindrical form, the inner facing surfaces of the legs being flat and parallel, the anode extensions at the free ends of said legs on the inside surface thereof provided with oppositely disposed semicylindrical surfaces forming a cylindrical chamber extending parallel to and co-extensive with the flat surfaces of said legs, a blackened coating on the semi-cylindrical surfaces of said legs to increase the heat emissivity of said legs, a straight thermionic cathode positioned axially of said cylindrical chamber, means for producing a magnetic field longitudinally of said cathode, and non-magnetic shields positioned between the ends of the anode segments and the envelope of the tube at opposite ends of said straight thermionic cathode.
5. A magnetron having an elongated envelope closed at one end with a tubular metal member and containing an elongated U-shaped member, the legs of which have a comparatively large transverse cross section and are of comparatively large mass, the inner facing surfaces of said legs being closely spaced, flat and parallel, a pair of anode segments at the free end of said legs on the inside surfaces and having oppositely disposed semi-cylindrical surfaces providing a cylindrical chamber, the axis of which is parallel to the fiat surfaces of the legs of said U-shaped member, a straight thermionic cathode positioned axially of said cylindrical chamber and means for producing a magnetic field longitudinally of said cathode, the end of said U-shaped member opposite from said anode segments being Within and secured to said tubular metal member, and a cooling jacket surrounding said tubular metal member.
GEORGE R. KILGORE.
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US66379A US2075855A (en) | 1936-02-29 | 1936-02-29 | Magnetron |
FR818069D FR818069A (en) | 1936-02-29 | 1937-02-19 | Magnetron refinements |
GB6092/37A GB472583A (en) | 1936-02-29 | 1937-03-01 | Improvements in or relating to electron discharge devices |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US66379A US2075855A (en) | 1936-02-29 | 1936-02-29 | Magnetron |
Publications (1)
Publication Number | Publication Date |
---|---|
US2075855A true US2075855A (en) | 1937-04-06 |
Family
ID=22069127
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US66379A Expired - Lifetime US2075855A (en) | 1936-02-29 | 1936-02-29 | Magnetron |
Country Status (3)
Country | Link |
---|---|
US (1) | US2075855A (en) |
FR (1) | FR818069A (en) |
GB (1) | GB472583A (en) |
Cited By (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2423426A (en) * | 1943-11-13 | 1947-07-01 | Sylvania Electric Prod | Ultra high frequency tube of the resonator type |
US2426655A (en) * | 1944-12-11 | 1947-09-02 | Gen Electric | High-frequency electric discharge device |
US2429291A (en) * | 1943-07-01 | 1947-10-21 | Westinghouse Electric Corp | Magnetron |
US2431139A (en) * | 1943-06-23 | 1947-11-18 | Westinghouse Electric Corp | Magnetron |
US2438873A (en) * | 1944-05-24 | 1948-03-30 | Sylvania Electric Prod | Ultra high frequency switching device |
US2443179A (en) * | 1941-06-24 | 1948-06-15 | Submarine Signal Co | Electrical apparatus |
US2454970A (en) * | 1943-10-16 | 1948-11-30 | Gen Electric | Ultra high frequency electric discharge device |
US2476611A (en) * | 1945-02-07 | 1949-07-19 | Rca Corp | Electron discharge device |
US2537824A (en) * | 1946-03-30 | 1951-01-09 | Bell Telephone Labor Inc | Magnetron |
DE911523C (en) * | 1938-03-29 | 1954-05-17 | Int Standard Electric Corp | Ultra short wave tubes with cooling |
US3112423A (en) * | 1960-07-18 | 1963-11-26 | Burroughs Corp | Noise-generating tube |
-
1936
- 1936-02-29 US US66379A patent/US2075855A/en not_active Expired - Lifetime
-
1937
- 1937-02-19 FR FR818069D patent/FR818069A/en not_active Expired
- 1937-03-01 GB GB6092/37A patent/GB472583A/en not_active Expired
Cited By (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE911523C (en) * | 1938-03-29 | 1954-05-17 | Int Standard Electric Corp | Ultra short wave tubes with cooling |
US2443179A (en) * | 1941-06-24 | 1948-06-15 | Submarine Signal Co | Electrical apparatus |
US2431139A (en) * | 1943-06-23 | 1947-11-18 | Westinghouse Electric Corp | Magnetron |
US2429291A (en) * | 1943-07-01 | 1947-10-21 | Westinghouse Electric Corp | Magnetron |
US2454970A (en) * | 1943-10-16 | 1948-11-30 | Gen Electric | Ultra high frequency electric discharge device |
US2423426A (en) * | 1943-11-13 | 1947-07-01 | Sylvania Electric Prod | Ultra high frequency tube of the resonator type |
US2438873A (en) * | 1944-05-24 | 1948-03-30 | Sylvania Electric Prod | Ultra high frequency switching device |
US2426655A (en) * | 1944-12-11 | 1947-09-02 | Gen Electric | High-frequency electric discharge device |
US2476611A (en) * | 1945-02-07 | 1949-07-19 | Rca Corp | Electron discharge device |
US2537824A (en) * | 1946-03-30 | 1951-01-09 | Bell Telephone Labor Inc | Magnetron |
US3112423A (en) * | 1960-07-18 | 1963-11-26 | Burroughs Corp | Noise-generating tube |
Also Published As
Publication number | Publication date |
---|---|
FR818069A (en) | 1937-09-17 |
GB472583A (en) | 1937-09-27 |
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