US3045147A - Magnetron electrode structures - Google Patents

Magnetron electrode structures Download PDF

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US3045147A
US3045147A US853160A US85316059A US3045147A US 3045147 A US3045147 A US 3045147A US 853160 A US853160 A US 853160A US 85316059 A US85316059 A US 85316059A US 3045147 A US3045147 A US 3045147A
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anode
vanes
strap
pairs
strap pairs
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John R Butler
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Raytheon Co
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Raytheon Co
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J23/00Details of transit-time tubes of the types covered by group H01J25/00
    • H01J23/16Circuit elements, having distributed capacitance and inductance, structurally associated with the tube and interacting with the discharge
    • H01J23/18Resonators
    • H01J23/22Connections between resonators, e.g. strapping for connecting resonators of a magnetron

Definitions

  • the central portions of the vanes of the type of anode structure described above absorb only a small current density and, hence, the total current and power output being generated at the level of operation at which arcing occurs will be relatively low in an anode the RF field of which has maxima at the ends of the vanes.
  • anode structure in which the electric field distribution along the anode vane is uniform.
  • the anode current may be increased to a greater value before arcing occurs at any point along the vane.
  • full advantage of the energy transfer all along the vane is obtained.
  • Prior art anode vane structures do not provide such a uniform electric field distribution.
  • This invention provides a uniform distribution of electric field energy along the anode vanes of a magnetron in the direction of the longitudinal axis of the tube.
  • This uniform distribution is achieved in a preferred embodiment of the invention by utilizing a plurality of strap pairs positioned at selectable points along the lengths of the anode vanes.
  • the strap pairs near the upper and lower ends of the anode vanes are arranged to have a greater D.-C. capacitance than those provided at the central regions of the vanes.
  • the strap pairs are substantially symmetrically placed along the lengths of the anode vanes so that the distance from each end of the anode vanes to the nearest strappair is substantially equal 3,045,147 Patented July 17, 1962
  • FIGS. 3 and 4 show cross-sectional views of the anode structure of the invention.
  • FIGS. 1, 3 and 4 show a preferred embodiment of the invention wherein a plurality of strap pairs are positioned so that they are substantially aligned along the length of the anode vanes in the direction of the longitudinal axis of the tube.
  • a pair of anode vanes 10 and 11 oppositely disposed with respect to a cathode 15.
  • Vanes 10 and 11 represent two of a plurality of similar vanes radially spaced about cathode 15 in accordance with conventional magnetron structure.
  • a pair of straps 18 is placed at a distance substantially equal to t from the upper ends of vanes 10 and 11. Additional substantially equal to and the distance from strap pair 21 to the lower ends of vanes 10 and 11 is substantially equal to
  • the upper straps of each pair are connected to alternating anode vanes and the lower straps of each pair are connected to intermediate anode vanes as is conventional in magnetron anode structures.
  • vane 10 represents one of the alternating vanes to which the upper straps are connected and vane 11 represents one of the intermediate vanes to which the lower straps are con-l nected.
  • the size of strap pairs 18 and 21 neanthe upper and lower regions of the vanes is greater than the size of strap pairs 19 and 20 positioned in the central regions of the vanes.
  • greater D.-C. capacitance is provided by the straps near the upper and lower ends of the vanes.
  • the D.-C. capacitance of straps 13 and 21 is substantially twice the D-.-C. capacitance of straps 19 and 20.
  • FIG. 2 The electric field energy distribution for the structure of FIG. 1" is shown in FIG. 2 wherein solid curve 17 represents the electric field strength plotted along the length L of the vanes.
  • FIGS. 1, 3 and 4 does not necessarily represent the only embodiment of the-invention inasmuch as other embodiments will occur to those skilled in the art without departing from the scope of the invention.
  • a number of strap pairs other than the four shown in the figures may be used depending upon the size of the anode structure 'desiredand the wavelength of the resonant frequency of the anode. It should be realized that the weight of strapping utilized should'be distributed to provide a uniformfield and that such a distribution generally requires heavier strapping near the ends of the vane structures.
  • the straps at each end may be placed directly at the upper and lower end surfaces of the anode vanes rather than positioned inwardly from the ends as shown.
  • the specific embodiment shown utilizes strap pairs wherein the straps are placed one above the other, it is obvious that the straps may be alternatively positioned side by side in accordance with a conventional radial orientation.
  • the invention is not to be construed as limited to the specific structure shown and described herein except as defined by the appended claims.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap groups, a first quantity of each of said strap groups being connected to alternating ones of said anode vanes and a second quantity of each of said strap groups being connected to intermediate ones of said anode vanes, a first number of said strap groups having D.-C. capacitances different from the D.-C. capacitances of the remaining strap groups.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, a first group of said strap pairs having D.-C. capacitances different from the D.-C. capacitances of the remaining strap pairs.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, a first group of said strap pairs positioned near the ends of said anode vanes having D.-C. capacitances difierent from the D.-C. capacitances of the remaining strap pairs.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, a first group of said strap pairs positioned near the ends of said anode vanes having D.-C. capacitances greater than the D.-C. capacitances of the remaining strap pairs.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs symmetrically positioned along the lengths of said vanes, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest ones of said strap pairs adjacent said ends having D.-C. capacitances greater than the D.-C. capacitances of the remaining strap pairs.
  • an electrode struc ture comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs positioned along the lengths of said vanes, the distance between said strap pairs being substantially twice the distance from the upper and lower ends of said vanes to the nearestadjacent ones of said strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest ones of said strap pairs positioned near the ends of said anode vanes having D.-C. capacitances greater than the D.-C. capacitances of the remaining strap pairs.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs positioned along the lengths of said vanes, the distance between said strap pairs being substantially twice the dis tance from the upper and lower ends of said vanes to the nearest adjacent ones of said strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest adjacent ones of said strap pairs having D.-C. capacitances equal to substantially twice the D.-C. capacitances of the remaining strap pairs.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode, a plurality of conducting strap pairs positioned along the lengths of said vanes, the distance between said strap pairs being substantially twice the distance from the upper and lower ends of said vanes to the nearest adjacent ones of said strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest adjacent ones of said strap pairs having D.-C. capacitances equal to substantially twice the D.-C. capacitances of the remaining strap pairs.
  • an electrode structure comprising an anode cylinder; a plurality of anode vanes each having a length L, said vanes being attached to said anode cylinder and radially spaced about a cathode, four conducting strap pairs positioned along the length of said vanes, the distance between said strap pairs being substantially equal to and the distance from the upper and lower ends of said vanes to the nearest adjacent ones of said strap pairs being substantially equal to a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest adjacent ones of said strap pairs having D.-C. capacitances equal to twice the D.-C. capacitances of the remaining two strap pairs.

Description

July 17, 1962 J. R. BUTLER MAGNETRON ELECTRODE STRUCTURES 2 Sheets-Sheet 1 Filed Nov. 16, 1959 4 w L w w E m m \j \j W a E +L 8v l 4 4 4 L FIGI ELECTRIC FIELD STRENGTH INVENTOR JOHN R. BUTLE BY VW ATTORNEY July 17, 1962 J. R. BUTLER 'MAGNETRON ELECTRODE STRUCTURES 2 Sheets-Sheet 2 Filed Nov. 16, 1959 INVENTOR JOHN R. BUTLER l BY Wkm ATTORNEY United States Patent i 3,045,147 MAGNETRON ELECTRODE STRUCTURES John R. Butler, Lexington, Mass., assignor to Raytheon Company, Waltham, Mass., a corporation of Delaware Filed Nov. 16, 1959, Ser. No. 853,160
9 Claims. (Cl. SIS-39.69)
' and the RF electric field of the anode. The stronger the electric field, the greater is the current density and power transfer which occurs. In conventional strapped magnetrons which utilize a pair of straps positioned either at the upper or lower ends of the anode vanes or at both ends, a non-uniform distribution of the RF electric field exists along the anode vanes in the direction of the longitudinal axis of the magnetron and is greatest in those areas of .the anode adjacent the strap pairs. If the anode voltage is increased to provide an increase in total current and output power, a value of current density is ultimately reached near the regions where the straps are placed, which causes arcing to occur between the cathode and the anode vanes. The arcing and high current density result in tube instability, erosion of the vane tips, and damage to the emitting surface of the cathode.
The central portions of the vanes of the type of anode structure described above absorb only a small current density and, hence, the total current and power output being generated at the level of operation at which arcing occurs will be relatively low in an anode the RF field of which has maxima at the ends of the vanes.
It is, therefore, desirable to obtain an anode structure in which the electric field distribution along the anode vane is uniform. In such a structure the anode current may be increased to a greater value before arcing occurs at any point along the vane. Thus, full advantage of the energy transfer all along the vane is obtained. Prior art anode vane structures do not provide such a uniform electric field distribution.
This invention provides a uniform distribution of electric field energy along the anode vanes of a magnetron in the direction of the longitudinal axis of the tube. This uniform distribution is achieved in a preferred embodiment of the invention by utilizing a plurality of strap pairs positioned at selectable points along the lengths of the anode vanes. The strap pairs near the upper and lower ends of the anode vanes are arranged to have a greater D.-C. capacitance than those provided at the central regions of the vanes. Such a construction assures a uniform electric field distribution. In one particular embodiment of the invention, the strap pairs are substantially symmetrically placed along the lengths of the anode vanes so that the distance from each end of the anode vanes to the nearest strappair is substantially equal 3,045,147 Patented July 17, 1962 FIGS. 3 and 4 show cross-sectional views of the anode structure of the invention.
FIGS. 1, 3 and 4 show a preferred embodiment of the invention wherein a plurality of strap pairs are positioned so that they are substantially aligned along the length of the anode vanes in the direction of the longitudinal axis of the tube. In these figures there is shown a pair of anode vanes 10 and 11 oppositely disposed with respect to a cathode 15. Vanes 10 and 11 represent two of a plurality of similar vanes radially spaced about cathode 15 in accordance with conventional magnetron structure.
' The radially spaced anode .vanes are attached at their outer ends to an anode cylinder 12, a portion of which is shown in the figures.
If the length of anode vanes 10 and 11 as measured along the longitudinal axis of the tube is denoted by L,
a pair of straps 18 is placed at a distance substantially equal to t from the upper ends of vanes 10 and 11. Additional substantially equal to and the distance from strap pair 21 to the lower ends of vanes 10 and 11 is substantially equal to The upper straps of each pair are connected to alternating anode vanes and the lower straps of each pair are connected to intermediate anode vanes as is conventional in magnetron anode structures. In the figures, vane 10 represents one of the alternating vanes to which the upper straps are connected and vane 11 represents one of the intermediate vanes to which the lower straps are con-l nected.
As is evident inthe figures, the size of strap pairs 18 and 21 neanthe upper and lower regions of the vanes is greater than the size of strap pairs 19 and 20 positioned in the central regions of the vanes. Hence, greater D.-C. capacitance is provided by the straps near the upper and lower ends of the vanes. In the preferred embodiment shown in FIGS. 1, 3 and 4 the D.-C. capacitance of straps 13 and 21 is substantially twice the D-.-C. capacitance of straps 19 and 20. This unequal distribution of the weight of the strapping assures a uniform distribution of electric field energy along the lengths of the anode vanes. If equal weights of strapping are utilized for the strapped pairs, 'a non-uniform distribution would occur and a greater field strength would exist in the central regions of the vanes than at the ends.
The electric field energy distribution for the structure of FIG. 1" is shown in FIG. 2 wherein solid curve 17 represents the electric field strength plotted along the length L of the vanes.
The configuration shown in FIGS. 1, 3 and 4 does not necessarily represent the only embodiment of the-invention inasmuch as other embodiments will occur to those skilled in the art without departing from the scope of the invention. A number of strap pairs other than the four shown in the figures may be used depending upon the size of the anode structure 'desiredand the wavelength of the resonant frequency of the anode. It should be realized that the weight of strapping utilized should'be distributed to provide a uniformfield and that such a distribution generally requires heavier strapping near the ends of the vane structures.
need not necessarily be symmetrical and the straps at each end may be placed directly at the upper and lower end surfaces of the anode vanes rather than positioned inwardly from the ends as shown. Although the specific embodiment shown utilizes strap pairs wherein the straps are placed one above the other, it is obvious that the straps may be alternatively positioned side by side in accordance with a conventional radial orientation. Hence, the invention is not to be construed as limited to the specific structure shown and described herein except as defined by the appended claims.
What is claimed is:
1. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap groups, a first quantity of each of said strap groups being connected to alternating ones of said anode vanes and a second quantity of each of said strap groups being connected to intermediate ones of said anode vanes, a first number of said strap groups having D.-C. capacitances different from the D.-C. capacitances of the remaining strap groups.
2. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, a first group of said strap pairs having D.-C. capacitances different from the D.-C. capacitances of the remaining strap pairs.
3. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, a first group of said strap pairs positioned near the ends of said anode vanes having D.-C. capacitances difierent from the D.-C. capacitances of the remaining strap pairs.
4. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, a first group of said strap pairs positioned near the ends of said anode vanes having D.-C. capacitances greater than the D.-C. capacitances of the remaining strap pairs.
5. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs symmetrically positioned along the lengths of said vanes, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest ones of said strap pairs adjacent said ends having D.-C. capacitances greater than the D.-C. capacitances of the remaining strap pairs.
6. In an electron discharge device, an electrode struc ture comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs positioned along the lengths of said vanes, the distance between said strap pairs being substantially twice the distance from the upper and lower ends of said vanes to the nearestadjacent ones of said strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest ones of said strap pairs positioned near the ends of said anode vanes having D.-C. capacitances greater than the D.-C. capacitances of the remaining strap pairs.
7. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode; a plurality of conducting strap pairs positioned along the lengths of said vanes, the distance between said strap pairs being substantially twice the dis tance from the upper and lower ends of said vanes to the nearest adjacent ones of said strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest adjacent ones of said strap pairs having D.-C. capacitances equal to substantially twice the D.-C. capacitances of the remaining strap pairs.
8. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes attached to said anode cylinder and radially spaced about a cathode, a plurality of conducting strap pairs positioned along the lengths of said vanes, the distance between said strap pairs being substantially twice the distance from the upper and lower ends of said vanes to the nearest adjacent ones of said strap pairs, a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest adjacent ones of said strap pairs having D.-C. capacitances equal to substantially twice the D.-C. capacitances of the remaining strap pairs.
9. In an electron discharge device, an electrode structure comprising an anode cylinder; a plurality of anode vanes each having a length L, said vanes being attached to said anode cylinder and radially spaced about a cathode, four conducting strap pairs positioned along the length of said vanes, the distance between said strap pairs being substantially equal to and the distance from the upper and lower ends of said vanes to the nearest adjacent ones of said strap pairs being substantially equal to a first strap of each of said strap pairs being connected to alternating ones of said anode vanes and a second strap of each of said strap pairs being connected to intermediate ones of said anode vanes, said nearest adjacent ones of said strap pairs having D.-C. capacitances equal to twice the D.-C. capacitances of the remaining two strap pairs.
References Cited in the file of this patent UNITED STATES PATENTS 2,423,161 Spencer July 1, 1947 2,582,185 Willshaw Jan. 8, 1952 2,607,019 Dodds Aug. 12, 1952 2,745,040 Dunsmuir May 8, 1956 2,778,975 Dunsmuir Ian. 22, 1957 2,828,444 Wallace Mar. 28, 1958 2,871,407 Okress Jan. 27, 1959
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3423632A (en) * 1965-12-08 1969-01-21 Nippon Electric Co Electron discharge device construction
DE2938350A1 (en) * 1979-09-11 1981-04-09 Jurij Ignatevič Moskva Dodonov HIGHEST FREQUENCY DEVICE OF THE MAGNETRON TYPE
US4288721A (en) * 1979-06-20 1981-09-08 Dodonov J I Microwave magnetron-type device
US20220165534A1 (en) * 2020-11-26 2022-05-26 Teledyne Uk Limited Magnetron

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2423161A (en) * 1945-03-21 1947-07-01 Raytheon Mfg Co Electron discharge device of the plural cavity resonator type
US2582185A (en) * 1946-05-17 1952-01-08 M O Valve Co Ltd Cavity resonator magnetron
US2607019A (en) * 1948-05-29 1952-08-12 Rca Corp Electron discharge device of the cavity resonator type
US2745040A (en) * 1953-10-12 1956-05-08 British Thomson Houston Co Ltd Cavity type magnetrons
US2778975A (en) * 1952-11-18 1957-01-22 British Thomson Houston Co Ltd Magnetrons
US2828444A (en) * 1948-04-10 1958-03-25 Int Standard Electric Corp Cavity magnetron
US2871407A (en) * 1957-04-29 1959-01-27 Westinghouse Electric Corp Electron discharge device

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2423161A (en) * 1945-03-21 1947-07-01 Raytheon Mfg Co Electron discharge device of the plural cavity resonator type
US2582185A (en) * 1946-05-17 1952-01-08 M O Valve Co Ltd Cavity resonator magnetron
US2828444A (en) * 1948-04-10 1958-03-25 Int Standard Electric Corp Cavity magnetron
US2607019A (en) * 1948-05-29 1952-08-12 Rca Corp Electron discharge device of the cavity resonator type
US2778975A (en) * 1952-11-18 1957-01-22 British Thomson Houston Co Ltd Magnetrons
US2745040A (en) * 1953-10-12 1956-05-08 British Thomson Houston Co Ltd Cavity type magnetrons
US2871407A (en) * 1957-04-29 1959-01-27 Westinghouse Electric Corp Electron discharge device

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3423632A (en) * 1965-12-08 1969-01-21 Nippon Electric Co Electron discharge device construction
US4288721A (en) * 1979-06-20 1981-09-08 Dodonov J I Microwave magnetron-type device
DE2938350A1 (en) * 1979-09-11 1981-04-09 Jurij Ignatevič Moskva Dodonov HIGHEST FREQUENCY DEVICE OF THE MAGNETRON TYPE
US4284924A (en) * 1979-09-11 1981-08-18 Dodonov J I Microwave magnetron-type device
US20220165534A1 (en) * 2020-11-26 2022-05-26 Teledyne Uk Limited Magnetron
EP4006947A1 (en) * 2020-11-26 2022-06-01 Teledyne UK Limited Magnetron

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