US2530603A - Device for very high frequencies comprising a lead-through conductor carrying high-frequency energy - Google Patents

Device for very high frequencies comprising a lead-through conductor carrying high-frequency energy Download PDF

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US2530603A
US2530603A US685147A US68514746A US2530603A US 2530603 A US2530603 A US 2530603A US 685147 A US685147 A US 685147A US 68514746 A US68514746 A US 68514746A US 2530603 A US2530603 A US 2530603A
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lead
conductor
current
frequency energy
insulator
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US685147A
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Dorgelo Eduard Gerardus
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Hartford National Bank and Trust Co
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    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03HIMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
    • H03H2/00Networks using elements or techniques not provided for in groups H03H3/00 - H03H21/00
    • H03H2/005Coupling circuits between transmission lines or antennas and transmitters, receivers or amplifiers
    • H03H2/006Transmitter or amplifier output circuits
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J25/00Transit-time tubes, e.g. klystrons, travelling-wave tubes, magnetrons
    • H01J25/02Tubes with electron stream modulated in velocity or density in a modulator zone and thereafter giving up energy in an inducing zone, the zones being associated with one or more resonators
    • H01J25/06Tubes having only one resonator, without reflection of the electron stream, and in which the modulation produced in the modulator zone is mainly velocity modulation, e.g. Lüdi-Klystron
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J5/00Details relating to vessels or to leading-in conductors common to two or more basic types of discharge tubes or lamps
    • H01J5/32Seals for leading-in conductors
    • H01J5/40End-disc seals, e.g. flat header
    • H01J5/42End-disc seals, e.g. flat header using intermediate part
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J2893/00Discharge tubes and lamps
    • H01J2893/0033Vacuum connection techniques applicable to discharge tubes and lamps
    • H01J2893/0034Lamp bases

Definitions

  • This invention relates to a device operating at very high frequencies of the order of magnitude X cycles per second and consequently in the region of decimeter wavelengths, and more particularly to the lead through of a high-frequency energy carrying conductor.
  • Such devices generally consist of the combination of an electric discharge tube of special design and a hollow body having conductive Walls.
  • box circuits or hollow space resonators stationary oscillations may develop; they are used, for instance, with magnetrons, velocity modulated tubes and the like.
  • Fig. 1 represents a. possible form of construction or a device in which the antenna extends in the vacuum chamber
  • Fig. 2 showing a common form of construction of a device comprising a leada through arrangement for the supply of highfrequency energy to an antenna outside the vacuum
  • Fig. 3 shows one form of construction in accordance with the invention
  • Fig. 4 shows one form of construction in accordance with the invention
  • the hollow body constituted by concentric conductors l6 and I! is designated I, the glass wall 2, the cathode 3, accelerating electrodes l and 5 and a collecting electrode 6, the assembly constituting the system of a velocity modulator tube.
  • the radiator 1 having a length of half a wavelength receives the high-frequency energy through the intermediary of a coupling loop 8 and a feed conductor 9.
  • the fastening insulator II is provided in the proximit of a, potential node in order to keep the dielectric losses low. Since in the present case the insulator ll need not form an air-tight junction, the problem of sealing the conductors 9 into the insulator does not exist. This construction, however, has the drawback of a poor robustness, since the combination of the conductors 9 and the radiator I cannot be supported in another way.
  • Fig. 2 A wellknown construction of such a device is shown in Fig. 2 in which corresponding parts bear the same reference numbers as in Fig. 1.
  • the insulator H must be sealed in an airtight manner to the metal wall of the hollow body I, it is necessary to make use of a sealing member to constitute a transition from the insulator to the said metal wall.
  • the hollow member consists of a conductive metal such as copper, silver or aluminium or is coated with such a metal at least at the inner surface,
  • the sealing member is shaped as a cy1inder I9 made from iernico or chrome iron.
  • the insulator should be connected to the leadthrough conductor 9 at a potential node to avoid high dielectric losses in the glass. Since, however, current and voltage are displaced by with respect to one another strong currents are induced on the sealing member Iii, which losses, due to the comparatively high resistance of fernico and chrome iron, involve high losses and consequently undesired heating. Hence a compromise must be adopted in the case of a seal according to Fig. 2.
  • a device for working with very high frequencies comprising a metal wall which consists at least at the inner surface of a material having a low resistance and through which is passed a high-frequency conveying conductor by means of a lead-through insulator Which is connected on the one hand to the said conductor and on the other hand, with the interposition of a metal sealing m mber made from a material perfectly adhering to glass but exhibiting higher losses, to the conductive wall, the lead-through insulator is given sucha shape as to be sealed as close as possible to a potential node to the lead-through conductor and as close as possible to a current node to the sealing member.
  • the lead-through insulator may preferably be shaped as a tube in which the lead-through conductor is provided parallel with the longitudinal axis and which is sealed about this conductor at one end and at the other end to a sealing member. If the length of the tubular lead-through conductor still amounts to wavelength, which is not ob-* jectionable in working with decimeter waves, it can be achieved that the sealing member is on a level with a point where the lead-through.
  • the size of the sealing to Figures 1 and 2 the reference number I designates the hollow resonator chamber whose wall consists, for instance, of copper and in which electromagnetic oscillations are generated by means of a velocity modulator tube.
  • the hollow chamber is traversed in an axial direction by an electron stream which is emitted at one end by a cathode 3 and upon traversing the hollow chamber is collected at the other end by a collecting electrode 6 which forms an assembly with the wall of the hollow chamber I.
  • This collecting electrode may be cooled with water.
  • the hollow chamber is closed in a manner known per se at the first-mentioned end by a glass member 2 in which are secured the cathode 3 and the accelerating electrodes 4 and 5 producing the electron stream.
  • the wall of the hollow chamber I is provided with a slit about which is soldered the metal tube l3 also consisting of copper.
  • a junction member in the form of a narrow ring ID is soldered to the copper tube I3.
  • This junction ring Ii] may consist of fernico.
  • the glass inlet insulator II which may be shaped as a tube and is sealed to the lead-through conductors 9 at the other end I2.
  • the conductors 9 extend parallel with the axis of the tube I3 and unite to form a 100p at 3 at some depth within the hollow chamber I.
  • the loop is coupled with the field in the hollow chamber.
  • the current strength in the conductors 9, which constitute a Lecher system in the case under view, is a maximum in the loop 8, and there is a second maximum of current strength at I2.
  • the Lecher lines On a level with the sealing ring ll! the Lecher lines exhibit a current node but a maximum of potential, whereas the potential node is exactly at I2.
  • no dielectric losses are caused in the lead-through insulator at the seal l2 of the Lecher lines, and on the other hand no currents are induced on the fernico ring II).
  • the length of the lead-through insulator amounts to about wavelen th. and that of the conductors 9 to about wavelength.
  • FIG. 4 Another form of construction is represented in Fig. 4, where only one conductor 9 is used which projects into the hollow chamber I where the electric field is strongest.
  • the conductor 9 is partly surrounded by the copper tube I 3 which is connected to the hollow chamber 1 and sealed by means of the chrome iron sealing ring I! to the lead-through insulator I I having the shape of a glass tube.
  • the conductor 9 is sealed intothe glass at I2 exactly at a potential node.
  • stationary oscillations are produced along the conductor 9, as is i lustrated in the figure by curves 2' and e, the conductor 9 having a current node at M at the end extending in the hol-Q 4 low chamber and consequently about on a level with the sealing ring I0.
  • the part I of the conductor 9 freely projecting to the outside constitutes a radiator and has a Wavelength, from 12 onwards, of about wavelength.
  • the glass tube H is surrounded by the copper tube [3 which merges at I2 into a large fiat disc I5, as a result of which solely the freely projecting part I is able to radiate.
  • a high frequency device having a tubular Wall portion of low electrical surface resistance, a current carrying member positioned Within said tubular portion, extending therefrom and having a voltage and current distribution to produce thereon a current node and a potential node, and means to hermetically seal said current carrying member to the end of said tubular portion in an insulating manner, said means comprising an annular metal sealing member having a greater electrical surface resistance than said tubular portion positioned in spaced relationship to said current carrying member in the vicinity of a current node on said current member and secured to said tubular portion, and a tubular insulating member approximately one-quarter wavelength in length, having one end thereof secured to said annular member in the vicinity of said current node and the other end thereof secured to said current carrying member in the vicinity of a potential node on said current carrying member.
  • a high frequency device having a resonator with distributed electrical constants and a resonant frequency of the order of 3x10 cycles per second, comprising a tubular portion of low electrical surface resistance and open to said resonator, a Lecher-wire current carrying system positioned within said tubular portion having one end thereof extending from said tubular portion and having the other end thereof coupled to said resonator, and means to hermetically seal said Lecher-wire system to said tubular portion in an insulating manner, said means comprising an annular metal sealing member having a greater electrical surface resistance than said tubular portion positioned in spaced relationship to said Lecher-wire system in the vicinity of a current node on said system and secured to said tubular portion, and a tubular insulating member approximately one-quarter wavelength in length having one end thereof secured to said annular member in the vicinity of said current node and the other end thereof secured to said Lecher-wire system in the vicinity of a potential node on said Lecher-wire system.
  • a high frequency device having a metal enclosure and a circuit element positioned within said enclosure and having distributed electrical constants and a resonant frequency of the order of 3X10 cycles per second, comprising a tubular reentrant member of low electrical surface resistance hermetically sealed to said enclosure and having the inner end theerof posit oned ad ac nt to said circuit element in the vicinitv of a current node thereof, a current carrying memb r positioned within said tubular member coupled to said circuit element at a current node thereof and having a voltage and current distribution to produce thereon a current node and a potential node, 2d.
  • said means comprising ,an annular metal sealing member having a greater electrical surface resistance than said tubular member positioned in spaced relationship to said current carrying member and secured to said tu'- bular member at the inner end thereof, and a tubular insulating member surrounding said current carrying member and positioned within said reentrant member and having a first portion secured to said sealing member in the vicinity of said current node and a second portion secured to said current carrying member in the vicinity of a potential node on said current carrying member.

Description

Nov. 21, 1950 E. G. DORGELO 2,530,603
DEVICE FOR VERY HIGH FREQUENCIES COMPRISING A LEAD-THROUGH CONDUCTOR CARRYING HIGH-FREQUENCY ENERGY Filed July 20, 1946 2 Sheets-Sheet 1 AGE/VT Nov. 21, 1950 DQRGELO 2,530,603
DEVICE FOR VERY HIGH FREQUENCIES COMPRISING A LEAD-THROUGH CONDUCTOR CARRYING HIGH-FREQUENCY ENERGY Filed July 20, 1946 2 Sheets-Sheet 2 IN VEN TOR. 4. [mm/w emnwumomao BY% W Patented Nov. 21, 1950 DEVICE FOR VERY HIGH FREQUENCIES COMPRISING A LEAD-THROUGH CONDUC- TOR CARRYING HIGH-FREQUENCY EN- ERGY Eduard Gerardus Dorgelo, Eindhoven, Netherlands, assignor to Hartford National Bank and Trust Company, Hartford, Conn., as trustee Application July 20, 1946, Serial No. 685,147 In the Netherlands March 1, 1943 Section 1, Public Law 690, August 8, 1946 Patent expires March 1, 1963 3 Claims. (01. 178-44) This invention relates to a device operating at very high frequencies of the order of magnitude X cycles per second and consequently in the region of decimeter wavelengths, and more particularly to the lead through of a high-frequency energy carrying conductor.
Such devices generally consist of the combination of an electric discharge tube of special design and a hollow body having conductive Walls.
In such hollow bodies, so-called box circuits or hollow space resonators stationary oscillations may develop; they are used, for instance, with magnetrons, velocity modulated tubes and the like.
In all these devices the high-frequency energy in the hollow chamber is to be led to the outside, fcr instance for feeding an antenna. This may take place in various ways, as will be explained by reference to the accompanying drawing, given by wa of example. In this drawing Fig. 1 represents a. possible form of construction or a device in which the antenna extends in the vacuum chamber, Fig. 2 showing a common form of construction of a device comprising a leada through arrangement for the supply of highfrequency energy to an antenna outside the vacuum. Fig. 3 shows one form of construction in accordance with the invention and Fig. 4
illustrates another form of construction in accordance with the invention.
In Fig. 1, similarly to the remaining figures, the hollow body constituted by concentric conductors l6 and I! is designated I, the glass wall 2, the cathode 3, accelerating electrodes l and 5 and a collecting electrode 6, the assembly constituting the system of a velocity modulator tube. The radiator 1 having a length of half a wavelength receives the high-frequency energy through the intermediary of a coupling loop 8 and a feed conductor 9. The fastening insulator II is provided in the proximit of a, potential node in order to keep the dielectric losses low. Since in the present case the insulator ll need not form an air-tight junction, the problem of sealing the conductors 9 into the insulator does not exist. This construction, however, has the drawback of a poor robustness, since the combination of the conductors 9 and the radiator I cannot be supported in another way.
The solution illustrated in this figure is very simple, since the conductor carrying off the highfrequency energy need not pass in an air-tight manner through the wall of the hollow body.
' As a rule, however, it will be'desirable to lead the high-frequency energy from the vacuum chamber to the outside in order that the various radiators or other devices, for instance measuring devices or the like, may be connected to the conductor 9. The conductor 9, which may consist of one or a plurality of conductors, must be passed in an air-tight manner through the metal Wall of the hollow body 2, which in itself often forms part of the vacuum chamber. A wellknown construction of such a device is shown in Fig. 2 in which corresponding parts bear the same reference numbers as in Fig. 1. Since in this case the insulator H must be sealed in an airtight manner to the metal wall of the hollow body I, it is necessary to make use of a sealing member to constitute a transition from the insulator to the said metal wall. In fact, the hollow member consists of a conductive metal such as copper, silver or aluminium or is coated with such a metal at least at the inner surface,
'so that the insulator cannot be sealed directly to this wall.
In the well-known form of construction shown in Fig. 2 the sealing member is shaped as a cy1inder I9 made from iernico or chrome iron.
In this case it is also very desirable that the insulator should be connected to the leadthrough conductor 9 at a potential node to avoid high dielectric losses in the glass. Since, however, current and voltage are displaced by with respect to one another strong currents are induced on the sealing member Iii, which losses, due to the comparatively high resistance of fernico and chrome iron, involve high losses and consequently undesired heating. Hence a compromise must be adopted in the case of a seal according to Fig. 2.
The aforesaid drawbacks are avoided if according to the invention, in a device for working with very high frequencies and comprising a metal wall which consists at least at the inner surface of a material having a low resistance and through which is passed a high-frequency conveying conductor by means of a lead-through insulator Which is connected on the one hand to the said conductor and on the other hand, with the interposition of a metal sealing m mber made from a material perfectly adhering to glass but exhibiting higher losses, to the conductive wall, the lead-through insulator is given sucha shape as to be sealed as close as possible to a potential node to the lead-through conductor and as close as possible to a current node to the sealing member. To this end the lead-through insulator may preferably be shaped as a tube in which the lead-through conductor is provided parallel with the longitudinal axis and which is sealed about this conductor at one end and at the other end to a sealing member. If the length of the tubular lead-through conductor still amounts to wavelength, which is not ob-* jectionable in working with decimeter waves, it can be achieved that the sealing member is on a level with a point where the lead-through.
In this case, the size of the sealing to Figures 1 and 2 the reference number I designates the hollow resonator chamber whose wall consists, for instance, of copper and in which electromagnetic oscillations are generated by means of a velocity modulator tube. To this end the hollow chamber is traversed in an axial direction by an electron stream which is emitted at one end by a cathode 3 and upon traversing the hollow chamber is collected at the other end by a collecting electrode 6 which forms an assembly with the wall of the hollow chamber I. This collecting electrode may be cooled with water. The hollow chamber is closed in a manner known per se at the first-mentioned end by a glass member 2 in which are secured the cathode 3 and the accelerating electrodes 4 and 5 producing the electron stream.
The wall of the hollow chamber I is provided with a slit about which is soldered the metal tube l3 also consisting of copper. At I4 a junction member in the form of a narrow ring ID is soldered to the copper tube I3. This junction ring Ii] may consist of fernico. On the other side of this ring Ill is sealed the glass inlet insulator II which may be shaped as a tube and is sealed to the lead-through conductors 9 at the other end I2. The conductors 9 extend parallel with the axis of the tube I3 and unite to form a 100p at 3 at some depth within the hollow chamber I. The loop is coupled with the field in the hollow chamber. The current strength in the conductors 9, which constitute a Lecher system in the case under view, is a maximum in the loop 8, and there is a second maximum of current strength at I2. On a level with the sealing ring ll! the Lecher lines exhibit a current node but a maximum of potential, whereas the potential node is exactly at I2. As a result thereof no dielectric losses are caused in the lead-through insulator at the seal l2 of the Lecher lines, and on the other hand no currents are induced on the fernico ring II). In this case the length of the lead-through insulator amounts to about wavelen th. and that of the conductors 9 to about wavelength.
Another form of construction is represented in Fig. 4, where only one conductor 9 is used which projects into the hollow chamber I where the electric field is strongest. The conductor 9 is partly surrounded by the copper tube I 3 which is connected to the hollow chamber 1 and sealed by means of the chrome iron sealing ring I!) to the lead-through insulator I I having the shape of a glass tube. The conductor 9 is sealed intothe glass at I2 exactly at a potential node. In fact, stationary oscillations are produced along the conductor 9, as is i lustrated in the figure by curves 2' and e, the conductor 9 having a current node at M at the end extending in the hol-Q 4 low chamber and consequently about on a level with the sealing ring I0. Therefore the induction losses in the ring In are low. The part I of the conductor 9 freely projecting to the outside constitutes a radiator and has a Wavelength, from 12 onwards, of about wavelength. The glass tube H is surrounded by the copper tube [3 which merges at I2 into a large fiat disc I5, as a result of which solely the freely projecting part I is able to radiate.
The drawing represents only two examples of the invention but it will be appreciated that it may also be realised in a different way.
What I claim is:
1. A high frequency device having a tubular Wall portion of low electrical surface resistance, a current carrying member positioned Within said tubular portion, extending therefrom and having a voltage and current distribution to produce thereon a current node and a potential node, and means to hermetically seal said current carrying member to the end of said tubular portion in an insulating manner, said means comprising an annular metal sealing member having a greater electrical surface resistance than said tubular portion positioned in spaced relationship to said current carrying member in the vicinity of a current node on said current member and secured to said tubular portion, and a tubular insulating member approximately one-quarter wavelength in length, having one end thereof secured to said annular member in the vicinity of said current node and the other end thereof secured to said current carrying member in the vicinity of a potential node on said current carrying member.
2. A high frequency device having a resonator with distributed electrical constants and a resonant frequency of the order of 3x10 cycles per second, comprising a tubular portion of low electrical surface resistance and open to said resonator, a Lecher-wire current carrying system positioned within said tubular portion having one end thereof extending from said tubular portion and having the other end thereof coupled to said resonator, and means to hermetically seal said Lecher-wire system to said tubular portion in an insulating manner, said means comprising an annular metal sealing member having a greater electrical surface resistance than said tubular portion positioned in spaced relationship to said Lecher-wire system in the vicinity of a current node on said system and secured to said tubular portion, and a tubular insulating member approximately one-quarter wavelength in length having one end thereof secured to said annular member in the vicinity of said current node and the other end thereof secured to said Lecher-wire system in the vicinity of a potential node on said Lecher-wire system.
3. A high frequency device having a metal enclosure and a circuit element positioned within said enclosure and having distributed electrical constants and a resonant frequency of the order of 3X10 cycles per second, comprising a tubular reentrant member of low electrical surface resistance hermetically sealed to said enclosure and having the inner end theerof posit oned ad ac nt to said circuit element in the vicinitv of a current node thereof, a current carrying memb r positioned within said tubular member coupled to said circuit element at a current node thereof and having a voltage and current distribution to produce thereon a current node and a potential node, 2d. means t h rm tica l alfia p ur e t ar.-
iying member within said tubular member in an insulating manner, said means comprising ,an annular metal sealing member having a greater electrical surface resistance than said tubular member positioned in spaced relationship to said current carrying member and secured to said tu'- bular member at the inner end thereof, and a tubular insulating member surrounding said current carrying member and positioned within said reentrant member and having a first portion secured to said sealing member in the vicinity of said curent node and a second portion secured to said current carrying member in the vicinity of a potential node on said current carrying member.
EDUARD GERARDUS DORGELO.
f REFERENCES CITED I The following references are of record in the file of this patent UNITED" STATES PATENTS 5 Number Name Date 2,114,114 Roberts Apr. 2, 1938 2,312,919 Litton a Mar. 2, 1943 2,351,744 I Cheyigny June 20, 1944 10 2,872,429 Jones -5 Mar. 27, 1945 2,394,398 1 Montmoursefi et al. Feb. 5, 1946 2,404,085 Okress et al. ..,l July 16, 1946 2,408,271 Rigiod et a1 Sept. 24, 1946
US685147A 1943-03-01 1946-07-20 Device for very high frequencies comprising a lead-through conductor carrying high-frequency energy Expired - Lifetime US2530603A (en)

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BE (1) BE454606A (en)
CH (1) CH243723A (en)
DE (1) DE879855C (en)
FR (1) FR902235A (en)
GB (1) GB624452A (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2855543A (en) * 1953-04-30 1958-10-07 Gen Electric Microwave beam transmitter
US3025395A (en) * 1958-11-19 1962-03-13 North American Aviation Inc Resonant cavity type radio frequency converter

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2114114A (en) * 1935-11-05 1938-04-12 Rca Corp Oscillatory system
US2312919A (en) * 1940-09-19 1943-03-02 Int Standard Electric Corp Modulation system for velocity modulation tubes
US2351744A (en) * 1942-12-24 1944-06-20 Standard Telephones Cables Ltd High-frequency vacuum tube oscillator
US2372429A (en) * 1942-10-31 1945-03-27 Rca Corp Spark plug
US2394398A (en) * 1942-03-20 1946-02-05 Westinghouse Electric Corp Coaxial line seal
US2404085A (en) * 1942-04-24 1946-07-16 Westinghouse Electric Corp Coaxial line
US2408271A (en) * 1942-08-12 1946-09-24 Westinghouse Electric Corp Coaxial terminal assembly

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2114114A (en) * 1935-11-05 1938-04-12 Rca Corp Oscillatory system
US2312919A (en) * 1940-09-19 1943-03-02 Int Standard Electric Corp Modulation system for velocity modulation tubes
US2394398A (en) * 1942-03-20 1946-02-05 Westinghouse Electric Corp Coaxial line seal
US2404085A (en) * 1942-04-24 1946-07-16 Westinghouse Electric Corp Coaxial line
US2408271A (en) * 1942-08-12 1946-09-24 Westinghouse Electric Corp Coaxial terminal assembly
US2372429A (en) * 1942-10-31 1945-03-27 Rca Corp Spark plug
US2351744A (en) * 1942-12-24 1944-06-20 Standard Telephones Cables Ltd High-frequency vacuum tube oscillator

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2855543A (en) * 1953-04-30 1958-10-07 Gen Electric Microwave beam transmitter
US3025395A (en) * 1958-11-19 1962-03-13 North American Aviation Inc Resonant cavity type radio frequency converter

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DE879855C (en) 1953-06-15
BE454606A (en)
CH243723A (en) 1946-07-31
FR902235A (en) 1945-08-22
GB624452A (en) 1949-06-08

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