US2659027A - Output connection for magnetron - Google Patents
Output connection for magnetron Download PDFInfo
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- US2659027A US2659027A US236446A US23644651A US2659027A US 2659027 A US2659027 A US 2659027A US 236446 A US236446 A US 236446A US 23644651 A US23644651 A US 23644651A US 2659027 A US2659027 A US 2659027A
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- magnetron
- resonator
- impedance
- conductor
- output system
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J23/00—Details of transit-time tubes of the types covered by group H01J25/00
- H01J23/36—Coupling devices having distributed capacitance and inductance, structurally associated with the tube, for introducing or removing wave energy
- H01J23/40—Coupling devices having distributed capacitance and inductance, structurally associated with the tube, for introducing or removing wave energy to or from the interaction circuit
- H01J23/48—Coupling devices having distributed capacitance and inductance, structurally associated with the tube, for introducing or removing wave energy to or from the interaction circuit for linking interaction circuit with coaxial lines; Devices of the coupled helices type
Definitions
- This invention relates to a system for extracting power from magnetrons and particularly to such a system which is capable of functioning efficiently over a wide band of frequencies.
- the invention provides a magnetron capable of application to many uses requiring a varied range of frequencies. Such a magnetron is valuable in laboratoryexperimental work where it may be applied toa wide variety of uses requiring adjustability over wide ranges of frequencies.
- the invention employs what may be termed a current coupling function as an output power conducting means rather than an inductive coupling such as takes place in looped type output coupling means.
- Power is extracted from the magnetron in the present invention by utilizing a structure which involves a minimum of change in the geometrical symmetry of the resonator elements of the magnetron.
- Such a structure results in efficient overall operation of the magnetron and provides for incorporating an efiicient broad band means for conducting power therefrom to a coaxial transmission line.
- a suitable mechanism (not shown) is provided for tuning the magnetron throughout the desired range of frequencies.
- the invention is herein described in connection with a magnetron having a resonator system the cavities of which are separated by a plurality of vanes or segments.
- the general aspects of the resonator structure, the cathode and a source of the applied magnetic field may be con ventional.
- the novel features reside in the manner of extracting power from the resonator system.
- To do this one of the vanes or segments in the resonator is isolated mechanically and electrically from the other segments and the wall structure of the magnetron anode.
- This isolated segment desirably has the same dimensions and relative dispositionwithln the resonator as the other segments. Itiis supported and desirably madeintegral withlan extension of the inner conductor of the coaxial line into which the power from the magnetron is fed.
- a short portion of the coaxial line adjacent to the magnetron contains the output elements and will be described as the output system of the magnetron.
- the inner conductor of this output system is supported within a conical chamber formed in the outer member thereof.
- the outer member opens into the resonator chamber of the magnetron and both members are'designed to present a desired pattern of impedance change extending from the magnetron to the coaxial transmission line.
- the output system is constructed to present a relatively low impedance at its inner end and a gradually increasing impedance as it extends outwardly to the point where it joins the coaxial transmission line.
- the manner of varying the impedance will be more fully described hereinafter.
- a further object of the invention is to provide a magnetron which is both functionally and structurally efl'icient.
- a still further object of the invention is to provide a magnetron having an output connection capable of extracting power from the magnetron with relatively high efliciency over a wide 4 band of frequencies.
- A' still further object of the invention is to provide a magnetron having a structure which may be fabricated by followin relatively simple techniques.
- a still further object of the invention is to provide a magnetron having the characteristics above mentioned together with the ability to produce relatively large amounts of power.
- Fig. 1 is a cross-sectional view angles to the axis of the cathode thereof.
- Fig. 2 is a cross-section taken on line 2-2 of Fig. 1. l
- Fig. 4 is a cross-sectional view similar to Fig.
- Fig. 3 is a cross-section taken on line. 3-3" formed in the anode block I and which oollec tively constitute the main resonating space of v the magnetron.
- the cham a ne separated from one another by a plurality oi ranes oif do J ments 3 which are arrangedradially and whoseinner ends define the centralizspace li within:
- the device is energized in theus'ual way'and and within the outer member I Of the coaxial line and the outer member ll of the output system.
- the member 9 may be held in spaced relation to the outer mem ber I4 of the output system in any suitable manner. As shown, herein; a plurality of small bloclgs of quartz l5 are inserted in the peripherynn the inner-end -of member 9. The blocks I5 extend into engagement with the sur- 1 face of the outer member I4 as shown in detail in-Eig. 2.-- Thus the inner member is held con- :on'trically within the outer member in a manner whioh will withstand a maximum output current t disintegration or damage to the strucure; Dosirablya't or near the outer end of the member Baa seal; I6 is provided which supports is provided with a source of magnetic flux,.
- the invention resides the means employed for. extr tin power om th dev ce olo th the anode block I is extended radially to embrace a power output system which.
- the inner m m e 5 s ce ve within a ca chamber n t e u e member di e in o wardly from a minimum diameter at its inner end, adjacent o he resonat r. space, t a max u diameter equal to the integral diameter. of the outer member I of the coaxial line, at or near its point ofjunction with the output system.
- the member 9 is constructed to present a varying diameter which in turn varies the impedance it presents along its length. For example, the impedance may vary from 14 ohms at its inner end to;52 ohms which isth'at oi the coaxial line.
- the desired gradual change in impedance from the small end of the conical chamber to a plane at or beyond the outer end of the chamber is o tained- Th fina mat i of p ce o the coaxial line as shown in Fig. 1 is done by gradually conforming the diameter of the member. 9 to that of the member -8 of the coaxial line.
- the extreme inner. end of the member 9 has a short cylindrical portionII which enters a com plementary cylindrical aperture in the anode bjo'dy opening into the resonator spaceof the magnetron.
- the portion II desirably terminates at the outer wall I2 of the resonator space and has integrally connected thereto a segment EI3 which desirably is the same size and shape as the other segments 3 of the resonator system.
- the segmentI-S is integrally connected to the inner end face of the section I I of the member 9;
- the coaxial lineinner member 8 the member 9 and segment I3 constitute an integral structure "which is supportedin spaced relation to the member 9 and also functions to isolate the vacuum space within the magnetron from the air filled coaxial line.
- a heat resisting ceramic material is used for the seal.
- means may be provided for cooling the member 9 wh'ile the device is operated at full power. This may be done in any desired manner such as that shownin the drawings in Fig. 1 wherein the member 9 is provided 'with'interconnected water cool: ing channels I! extending longitudinally thereof The channels I-I-are desirably extended outwardly to a point beyond" the vacuums'pace or the magnetron and are connected to inlet and outlet Water feeding tubes I8.”
- the water feeding tubes may e m o ass o other ce mic aterial
- the member IQ corresponding to the member 8 in the, other form or the invention is made rela tively' short and consequently causes a more ab: rupt change impedance throughout its len th; Ii this sho t or o ou put ys em t e chan e in impedance dueto the member I9 covers a reducedrange of frequencies.
- additional m ans are employed in the form of a sharp reductionin diameter of the member I9 at its junction with the inner member 8 of the coaxial transmission line.v
- the shoulder 2I1 acts to transform the impedanceof. the member 9 to that of the coaxial line.
- ih ooso h cam-11a was esters from one tube and leaves'thfough the other.
- the tubes are rigidly connected to the inner member and serve to support it in spaced relation to the outer member.
- a magnetron having an internal resonator system presenting an anode structure having a plurality of resonator cavities separated by radially disposed anode segments and a cathode supported centrally between the inner ends of said segments; a power output system for the magnetron comprising an outer hollow conductor integrally connected to said'anode structure and opening into the resonator space thereof, said hollow conductor being aligned with said coaxial line, an inner member for said output system coupled to the inner member of said coaxial line and supported in spaced relation to said outer member of said output system with the face of its inner end disposed substantially in alignment with the outer wall of said resonator space and having one of said resonator segments connected to and supported solely thereby.
- a magnetron having an internal resonator system presenting an anode structure having a plurality of resonator cavities separated by radially disposed anode segments and a cathode supported centrally between the inner ends of said segments; a power output system for said magnetron including power extracting means having an inner conductor and an outer hollow conductor, the latter opening into said resonator space, said outer conductor being aligned and coupled at its outer end to the outer member of said coaxial line, said inner conductor being coupled to the inner member of said coaxial line and supported in spaced relation to said outer member and having one of the segments of said resonator system connected to and supported solely thereby, said inner conductor having a conformation relative to the outer member to provide a constantly changing reactance to the passage of power from the magnetron to the coaxial transmission line.
- a magnetron having an internal resonator system presenting an anode structure having a resonator space including a plurality of resonator cavities separated by radially disposed anode segments and a cathode supported centrally between the ends of said segments; a power output system for the magnetron comprising an irmer conductor, a hollow outer conductor opening into said resonator space surrounding and held in spaced relation to said inner conductor, each conductor being connected respectively to the inner and outer conductors of said coaxial transmission line, said inner conductor having a contour coordinated with the chamber of said outer member to present an impedance varying smoothly according to a predetermined pattern involving curved contours for at least one of said conductors from a minimum at its inner end to a value substantially matching that of said coaxial line and a conductor connected to the inner end of said inner conductor and supported solely thereby said conductor extending into said resonator chamber between an adjacent pair of resonator cavities
- a power output system having the elements defined in claim 3 and in which said inner and outer conductors present an impedance varying from a minimum at their inner end to a value substantially matching that of the coaxial line and changing with distance at an exponential rate.
- An output system for high frequency magnetrons as defined in claim 2 in which the inner and outer conductors of said output system present a varying impedance along the length thereof and in which at least one of said conductors varies its impedance changing diameter to present a smoothly curved outline ending outwardly tangently to the uniform diameter of the coaxial element to which it is coupled.
- a power output system for said magnetron including power extracting means having an inner conductor and an outer hollow conductor, the latter opening into said resonator space, said outer conductor being aligned and coupled at its outer end to the outer member of said coaxial line, said inner conductor being coupled to the inner member of said coaxial line and supported in spaced relation to said outer member and having one of the segments of said resonator system connected to and supported thereby, a vacuum sealing means adjacent the plane of coupling between the said power output system and the coaxial line separating the evacuated magnetron cavities from the air-filled line, said inner and outer conductors of said output system presenting a varying impedance along the length thereof, and in which the impedance from the inner end of the system to the vacuum
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Description
Nov. 10, 1953 TONKS ET AL 2,659,027
OUTPUT CONNECTION FOR MAGNETRON Filed July .12, 1951 FIG. I
, 23 FIG. 4 L? 3 INVENTORS ew ONKS J05 F. HULL Patented Nov. 10, 1953 OUTPUT CONNECTION FOR MAGNETRON Lewi Tonks. Scotia, N. Y.', and Joseph F. Hull, Asbury Park, N. J., assignors to the United States of America as represented by the Secretary of the Army Application July 12, 1951, Serial No. 236,446
6 Claims. (01. 315-39) This invention relates to a system for extracting power from magnetrons and particularly to such a system which is capable of functioning efficiently over a wide band of frequencies.
In applying magnetrons to the many and varied uses requiring microwave power, a large number of types have been developed each of which is usually adapted to perform with satisfactory efiiciency when used in connection with a certain type of load, under certain ambient conditions or by reason of some other practical circumstance. The present invention departs from this general pattern of adaptability in that it provides for extracting power from the magnetron with high efiiciency over a wide band of frequencies, and moreover it is capable of extracting relatively large amounts of power.
The invention provides a magnetron capable of application to many uses requiring a varied range of frequencies. Such a magnetron is valuable in laboratoryexperimental work where it may be applied toa wide variety of uses requiring adjustability over wide ranges of frequencies.
The invention employs what may be termed a current coupling function as an output power conducting means rather than an inductive coupling such as takes place in looped type output coupling means. Power is extracted from the magnetron in the present invention by utilizing a structure which involves a minimum of change in the geometrical symmetry of the resonator elements of the magnetron. Such a structure results in efficient overall operation of the magnetron and provides for incorporating an efiicient broad band means for conducting power therefrom to a coaxial transmission line. A suitable mechanism (not shown) is provided for tuning the magnetron throughout the desired range of frequencies.
The invention is herein described in connection with a magnetron having a resonator system the cavities of which are separated by a plurality of vanes or segments. The general aspects of the resonator structure, the cathode and a source of the applied magnetic field may be con ventional. The novel features reside in the manner of extracting power from the resonator system. To do this one of the vanes or segments in the resonator is isolated mechanically and electrically from the other segments and the wall structure of the magnetron anode. This isolated segment desirably has the same dimensions and relative dispositionwithln the resonator as the other segments. Itiis supported and desirably madeintegral withlan extension of the inner conductor of the coaxial line into which the power from the magnetron is fed.
A short portion of the coaxial line adjacent to the magnetron contains the output elements and will be described as the output system of the magnetron. The inner conductor of this output system is supported within a conical chamber formed in the outer member thereof. The outer member opens into the resonator chamber of the magnetron and both members are'designed to present a desired pattern of impedance change extending from the magnetron to the coaxial transmission line.
' The output system is constructed to present a relatively low impedance at its inner end and a gradually increasing impedance as it extends outwardly to the point where it joins the coaxial transmission line. The manner of varying the impedance will be more fully described hereinafter.
It is an object of the present invention to provide means for increasing the scope of'usefulness of a magnetron.
A further object of the invention is to provide a magnetron which is both functionally and structurally efl'icient.
A still further object of the invention is to provide a magnetron having an output connection capable of extracting power from the magnetron with relatively high efliciency over a wide 4 band of frequencies.
A' still further object of the invention is to provide a magnetron having a structure which may be fabricated by followin relatively simple techniques.
A still further object of the invention is to provide a magnetron having the characteristics above mentioned together with the ability to produce relatively large amounts of power.
Other objects and features of the invention will more fully appear from the following description and will be particularly pointed out in the accompanying claims.
To present a better understanding of the invention particular embodiments thereof will be described and illustrated in the drawings in which:
Fig. 1 is a cross-sectional view angles to the axis of the cathode thereof.
Fig. 2 is a cross-section taken on line 2-2 of Fig. 1. l
Fig. 4.
Fig. 4 is a cross-sectional view similar to Fig.
taken at right Fig. 3 is a cross-section taken on line. 3-3" formed in the anode block I and which oollec tively constitute the main resonating space of v the magnetron. The cham a ne separated from one another by a plurality oi ranes oif do J ments 3 which are arrangedradially and whoseinner ends define the centralizspace li within:
which is received a cathode which is or may be of conventional construction The device is energized in theus'ual way'and and within the outer member I Of the coaxial line and the outer member ll of the output system.
The member 9 may be held in spaced relation to the outer mem ber I4 of the output system in any suitable manner. As shown, herein; a plurality of small bloclgs of quartz l5 are inserted in the peripherynn the inner-end -of member 9. The blocks I5 extend into engagement with the sur- 1 face of the outer member I4 as shown in detail in-Eig. 2.-- Thus the inner member is held con- :on'trically within the outer member in a manner whioh will withstand a maximum output current t disintegration or damage to the strucure; Dosirablya't or near the outer end of the member Baa seal; I6 is provided which supports is provided with a source of magnetic flux,. notshown, applied axially of the cathode thereby providin r g nera n hi irs us o Pow The invention resides the means employed for. extr tin power om th dev ce olo th the anode block I is extended radially to embrace a power output system which. is directly connec ed o a coa l tra smi n ne This extension of the anode constitutes the outer membe o the o t ut ys m an is c u e to the uter member 1 oi the axial transm i l n 7 The inner member 3 of the coaxial line is made coex ensive w h he inner mem 's i t e u put system. The member 9 is especially constructed to present a variable impedance throughout its length in a manner which will be described hereinafter. The output system in cluding the extension of the magnetron anode and the inner member 9 n1ay be considered as a transducer unit between the magnetron and its coaxial transmission line.
The inner m m e 5 s ce ve within a ca chamber n t e u e member di e in o wardly from a minimum diameter at its inner end, adjacent o he resonat r. space, t a max u diameter equal to the integral diameter. of the outer member I of the coaxial line, at or near its point ofjunction with the output system. The member 9; is constructed to present a varying diameter which in turn varies the impedance it presents along its length. For example, the impedance may vary from 14 ohms at its inner end to;52 ohms which isth'at oi the coaxial line. By controlling the outline curve of the member .9. the desired gradual change in impedance from the small end of the conical chamber to a plane at or beyond the outer end of the chamber is o tained- Th fina mat i of p ce o the coaxial line as shown in Fig. 1 is done by gradually conforming the diameter of the member. 9 to that of the member -8 of the coaxial line.
The extreme inner. end of the member 9 has a short cylindrical portionII which enters a com plementary cylindrical aperture in the anode bjo'dy opening into the resonator spaceof the magnetron. The portion II desirably terminates at the outer wall I2 of the resonator space and has integrally connected thereto a segment EI3 which desirably is the same size and shape as the other segments 3 of the resonator system. The segmentI-S is integrally connected to the inner end face of the section I I of the member 9; Thusthe coaxial lineinner member 8, the member 9 and segment I3 constitute an integral structure "which is supportedin spaced relation to the member 9 and also functions to isolate the vacuum space within the magnetron from the air filled coaxial line. Desirably a heat resisting ceramic material is used for the seal. 'If desired means may be provided for cooling the member 9 wh'ile the device is operated at full power. This may be done in any desired manner such as that shownin the drawings in Fig. 1 wherein the member 9 is provided 'with'interconnected water cool: ing channels I! extending longitudinally thereof The channels I-I-are desirably extended outwardly to a point beyond" the vacuums'pace or the magnetron and are connected to inlet and outlet Water feeding tubes I8." The water feeding tubes may e m o ass o other ce mic aterial The form ofthe invention shown in Fig. 1 provides a physically long output system wherein the'h'npedance may bemade tochange at a gradual rate determined by the length of the member e. As above stated, change of impedance c'a'nbe made follow a pattern represented by the contour of the curve.v i In Eigsjli and! a slig'htlydifferent form of the invention is shown. In this construction the variable portion of the "output system is rela tively short. This construction may be used where it may be "desirable to conserve space. The member IQ corresponding to the member 8 in the, other form or the invention is made rela tively' short and consequently causes a more ab: rupt change impedance throughout its len th; Ii this sho t or o ou put ys em t e chan e in impedance dueto the member I9 covers a reducedrange of frequencies. To cover the com vplete range of desired change of impedance, additional m ans are employed in the form of a sharp reductionin diameter of the member I9 at its junction with the inner member 8 of the coaxial transmission line.v The shoulder 2I1 acts to transform the impedanceof. the member 9 to that of the coaxial line. This construction pro vi lfi for a S ction 2i of the conductor I9 having a uniform diameter. A glass'or other ceramic vacu 'Seal is located at a position along this section where it will cause a minimum of dielectric loss thus contributing. to V the overall ef- -fioiencyoithe-magnetron. In the form ofithe'invention shownin Figs. 3 and 4=.a;rsupportingstructure for the inner end .of the inner member I 9 isshown' which also functions' as a'cool'ing means'. Apairofcuarter wave Stubs 22fproject -radially from the outer member of the? utput system and havemetamdwater circulating tubes" 'z a fe t nc n inward an l nected ro tne aiembe iilwhich is; apnoea with a charm ."4. ih ooso h cam-11a was esters from one tube and leaves'thfough the other. The tubes are rigidly connected to the inner member and serve to support it in spaced relation to the outer member.
What is claimed is:
1. In combination with a coaxial transmission line a magnetron having an internal resonator system presenting an anode structure having a plurality of resonator cavities separated by radially disposed anode segments and a cathode supported centrally between the inner ends of said segments; a power output system for the magnetron comprising an outer hollow conductor integrally connected to said'anode structure and opening into the resonator space thereof, said hollow conductor being aligned with said coaxial line, an inner member for said output system coupled to the inner member of said coaxial line and supported in spaced relation to said outer member of said output system with the face of its inner end disposed substantially in alignment with the outer wall of said resonator space and having one of said resonator segments connected to and supported solely thereby.
2. In combination with a coaxial transmission line a magnetron having an internal resonator system presenting an anode structure having a plurality of resonator cavities separated by radially disposed anode segments and a cathode supported centrally between the inner ends of said segments; a power output system for said magnetron including power extracting means having an inner conductor and an outer hollow conductor, the latter opening into said resonator space, said outer conductor being aligned and coupled at its outer end to the outer member of said coaxial line, said inner conductor being coupled to the inner member of said coaxial line and supported in spaced relation to said outer member and having one of the segments of said resonator system connected to and supported solely thereby, said inner conductor having a conformation relative to the outer member to provide a constantly changing reactance to the passage of power from the magnetron to the coaxial transmission line.
3. In combination with a coaxial transmission line a magnetron having an internal resonator system presenting an anode structure having a resonator space including a plurality of resonator cavities separated by radially disposed anode segments and a cathode supported centrally between the ends of said segments; a power output system for the magnetron comprising an irmer conductor, a hollow outer conductor opening into said resonator space surrounding and held in spaced relation to said inner conductor, each conductor being connected respectively to the inner and outer conductors of said coaxial transmission line, said inner conductor having a contour coordinated with the chamber of said outer member to present an impedance varying smoothly according to a predetermined pattern involving curved contours for at least one of said conductors from a minimum at its inner end to a value substantially matching that of said coaxial line and a conductor connected to the inner end of said inner conductor and supported solely thereby said conductor extending into said resonator chamber between an adjacent pair of resonator cavities and constitutin one of said segments.
4. A power output system having the elements defined in claim 3 and in which said inner and outer conductors present an impedance varying from a minimum at their inner end to a value substantially matching that of the coaxial line and changing with distance at an exponential rate.
5. An output system for high frequency magnetrons as defined in claim 2 in which the inner and outer conductors of said output system present a varying impedance along the length thereof and in which at least one of said conductors varies its impedance changing diameter to present a smoothly curved outline ending outwardly tangently to the uniform diameter of the coaxial element to which it is coupled.
6. In combination with a coaxial transmission line magnetron having an internal resonator system presenting an anode structure having a plurality of resonator cavities separated by radially disposed anode segments and a cathode supported centrally between the inner ends of said segments; a power output system for said magnetron including power extracting means having an inner conductor and an outer hollow conductor, the latter opening into said resonator space, said outer conductor being aligned and coupled at its outer end to the outer member of said coaxial line, said inner conductor being coupled to the inner member of said coaxial line and supported in spaced relation to said outer member and having one of the segments of said resonator system connected to and supported thereby, a vacuum sealing means adjacent the plane of coupling between the said power output system and the coaxial line separating the evacuated magnetron cavities from the air-filled line, said inner and outer conductors of said output system presenting a varying impedance along the length thereof, and in which the impedance from the inner end of the system to the vacuum sealing means changes by a value less than that required for matching said coaxial line, and an abrupt transforming means outside said vacuum seal to finally match the line impedance and wherein the initial impedance change is obtained by varying the diameter of the inner conductor to present a smoothly curved outline.
LEWI TONKS. JOSEPH F. HULL.
References Cited in the file of this patent UNITED STATES PATENTS Number
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US236446A US2659027A (en) | 1951-07-12 | 1951-07-12 | Output connection for magnetron |
Applications Claiming Priority (1)
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US236446A US2659027A (en) | 1951-07-12 | 1951-07-12 | Output connection for magnetron |
Publications (1)
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US2659027A true US2659027A (en) | 1953-11-10 |
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US236446A Expired - Lifetime US2659027A (en) | 1951-07-12 | 1951-07-12 | Output connection for magnetron |
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2817790A (en) * | 1954-07-26 | 1957-12-24 | Raytheon Mfg Co | Magnetron output coupling means |
US2822504A (en) * | 1953-11-09 | 1958-02-04 | Litton Industries Inc | Magnetron amplifier |
US2836764A (en) * | 1952-01-29 | 1958-05-27 | Raytheon Mfg Co | Magnetron output coupling devices |
US3065377A (en) * | 1959-12-12 | 1962-11-20 | Kenneth G Eakin | Microwave generator |
FR2137311A1 (en) * | 1971-05-18 | 1972-12-29 | Thomson Csf | |
US3885221A (en) * | 1973-03-02 | 1975-05-20 | English Electric Valve Co Ltd | Coupling arrangements in resonant devices |
US4115746A (en) * | 1975-12-06 | 1978-09-19 | English Electric Valve Company Limited | Multipactor discharge tuned resonant cavity devices |
US5006825A (en) * | 1987-10-16 | 1991-04-09 | Thomson-Cf | Coaxial line coupler with fluid cooled inner conductor |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2429291A (en) * | 1943-07-01 | 1947-10-21 | Westinghouse Electric Corp | Magnetron |
US2526399A (en) * | 1943-12-23 | 1950-10-17 | Westinghouse Electric Corp | Output connection for ultra high frequency devices |
-
1951
- 1951-07-12 US US236446A patent/US2659027A/en not_active Expired - Lifetime
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2429291A (en) * | 1943-07-01 | 1947-10-21 | Westinghouse Electric Corp | Magnetron |
US2526399A (en) * | 1943-12-23 | 1950-10-17 | Westinghouse Electric Corp | Output connection for ultra high frequency devices |
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2836764A (en) * | 1952-01-29 | 1958-05-27 | Raytheon Mfg Co | Magnetron output coupling devices |
US2822504A (en) * | 1953-11-09 | 1958-02-04 | Litton Industries Inc | Magnetron amplifier |
US2817790A (en) * | 1954-07-26 | 1957-12-24 | Raytheon Mfg Co | Magnetron output coupling means |
US3065377A (en) * | 1959-12-12 | 1962-11-20 | Kenneth G Eakin | Microwave generator |
FR2137311A1 (en) * | 1971-05-18 | 1972-12-29 | Thomson Csf | |
US3885221A (en) * | 1973-03-02 | 1975-05-20 | English Electric Valve Co Ltd | Coupling arrangements in resonant devices |
US4115746A (en) * | 1975-12-06 | 1978-09-19 | English Electric Valve Company Limited | Multipactor discharge tuned resonant cavity devices |
US5006825A (en) * | 1987-10-16 | 1991-04-09 | Thomson-Cf | Coaxial line coupler with fluid cooled inner conductor |
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