JP4301958B2 - Magnetron - Google Patents

Abstract

A magnetron comprises a cathode 5, an anode 2 having at least one vane 3, which defines a plurality of cavities. A dielectric resonator 7 is located between the vane(s) 3 and magnetic pole-piece 6a, such that it is in communication with said vane(s). The di-electric resonator 7 comprises a portion 8 of dielectric material, preferably a ceramic such as alumina, and a portion 9 of lossy material such as a carbon-loaded ceramic. A further conductive portion (15, figure 3) may be interposed between the two sections 8 and 9 of the resonator 7. In use the dielectric resonator 7 at least partially absorbs spurious radiation generated in a predetermined mode of operation of the magnetron, preferably the pi-1 mode, which if transmitted may interfere with other electronic devices.

Description

  The present invention relates to a magnetron.

In one known magnetron design, a central cylindrical cathode is surrounded by an anode structure that typically consists of a conductive cylinder, which supports a plurality of anode vanes that extend inwardly from the inner surface. . In operation, a magnetic field is applied in a direction parallel to the longitudinal axis of the cylindrical structure, combined with the electric field between the cathode and anode, affecting the electrons emitted by the cathode and consequently resonant. Occurs, and high-frequency energy is generated. The magnetron can support several oscillation modes that give a change in output frequency and power depending on the coupling between the cavities defined by the anode vanes. The normally required operating mode is called the pi operating mode.
It is desirable to be able to suppress the transmission of power generated in certain modes, such as the so-called pi-1 mode. It has been found that the power generated in this mode can interfere with other electronic devices such as mobile phones, satellite links, and other communication systems if transmitted. Various methods have been proposed to suppress this mode of operation, but these are usually expensive and complex and have been found to suppress radiation in the desired mode of operation, for example the pi mode. The present invention was born from research on magnetrons for ship radar applications. Such magnetrons are small, simple and low cost devices, and therefore low cost and straightforward solutions to the pi-1 radiation problem were sought.

The present invention provides a magnetron comprising an anode having at least one vane defining a plurality of cavities and a dielectric resonator, wherein a portion of the resonator is in a lossy state with at least one vane. And in use, the resonator is arranged to at least partially attenuate radiation generated in a predetermined mode of operation of the magnetron.
By providing a partially lossy dielectric material that communicates with one or more vanes, absorption of spurious radiation is provided.
The predetermined mode is preferably a pi-1 mode. By absorbing the radiation generated in this mode, interference with other electronic devices is prevented.
The lossy part of the resonator is preferably arranged further from the anode blade than the other part. This arrangement is advantageous because the electric field associated with the pi mode does not penetrate the resonator as deeply as the electric field associated with the pi-1 mode. Thus, the electrical energy generated in the pi-1 mode is attenuated more than the energy generated in the pi mode, thanks to the lossy distal portion.
Advantageously, the lossy part of the resonator is thinner than the other part, for example a quarter or less of the thickness of the other part.

The improved performance of the present invention can be achieved by the introduction of a conductive region sandwiched between the lossy part and the other part.
The resonator can include two annular members, one of which is lossy. The annular member can be coaxial. To achieve the aforementioned improved performance, additional annular conductive material can be sandwiched between the lossy member and the non-lossy member.
The dielectric resonator can include a ceramic material such as alumina. The lossy portion can be made of a ceramic material mixed with carbon.
The resonator can have an annular shape and is coaxial with the anode vane.
According to a second aspect of the present invention, means are provided for attenuating radiation generated by the magnetron in a predetermined mode of operation, the means being arranged to communicate with at least one anode vane of the magnetron. A resonator is provided.

The present invention will now be described by way of example only with reference to the accompanying drawings.
The same reference numerals are given to the same parts throughout the specification.
Referring to FIG. 1, the basic features of a conventional magnetron, generally designated 1 are shown. The main basic features include an anode 2 having a plurality of vanes 3, two of which are visible in this figure, 3a, 3b. When viewed from above, the vanes are equally spaced around the inner circumference of the cylindrical portion 4 of the anode 2 and extend inward therefrom, thereby forming a plurality of resonant cavities. The magnetron also includes a central cathode 5 surrounded by the anode 2. The magnetron 1 also includes pole pieces 6a and 6b arranged to generate a magnetic field required for the operation of the magnetron. The anode vane can be secured with a strap, which is not shown in this figure.

According to the present invention, the magnetron further comprises a dielectric resonator 7, a part of which is lossy. The resonator 7 is disposed in a space between the end of the anode blade 3 and one pole piece 6a in the magnetron, thereby communicating with a plurality of blades including the blades 3a and 3b. The resonator is also shown in communication with one pole piece 6a, but this is not necessarily so. In the present invention, it has been found that the pole pieces work equally well when they are spaced from the resonator 7.
In this embodiment, the resonator 7 is realized in the form of two annular members 8 and 9. The annular members 8, 9 are substantially coaxial and in intimate contact, but allow slight separation. The annular member 8 is made of a flat ceramic material with substantially no loss, and the annular member 9 is made of a lossy material such as a ceramic mixed with carbon powder. The annular members 8 and 9 are arranged such that the annular member 8 having no loss is sandwiched between the anode blades 3a and 3b and the annular member 9 having a large loss. The anode blades 3a, 3b and the annular members 8, 9 are also substantially coaxial.
The dimensions of the annular members 8 and 9 are predetermined so that the annular members resonate as dielectric resonators in the so-called TM110 mode. The resonator 7 is arranged to attenuate radiation generated in an undesirable mode of operation of the magnetron, such as the pi-1 mode, by magnetically coupling to the anode, thereby transmitting power in this mode. Suppress.

Reference is now made to FIG. 2, which is a graph showing the electric field strength plotted against the position along the thickness of the resonator. The vertical axis 10 represents the position where the anode vane meets the resonator, and the vertical axis 11 represents the position where the resonator meets the pole piece. The vertical axis 12 represents the junction between the lossy part and the lossless part of the resonator.
The upper line 13 represents the penetration of the TM110 electric field into the resonator in the pi-1 mode. The electric field is high throughout the depth of the resonator and is high even in the lossy part. Therefore, the lossy ceramic affects almost the entire pi-1 mode electric field. The diameter of the annular member is selected such that in the TM110 mode, the resonator has a resonance that matches the frequency of the pi-1 resonance of the anode. These two resonances are strongly coupled to each other by a common azimuthal magnetic field at the outer diameter, which translates resistance loss in the ceramic resonance into a relatively large series resistance in the pi-1 resonance, giving a low Q. In this way, the pi-1 mode is attenuated.

The other line 14 of this chart represents the fringe field penetration in the pi mode. A very small electric field enters the lossy part of the resonator, so that only a small portion of the electric field, typically less than 20%, is suppressed in the pi mode. However, it is preferable to minimize the reduction of the electric field generated in the pi mode, so that the magnetron according to FIG. 3 can be used.
The magnetron shown in FIG. 3 has the same characteristics as the magnetron of FIG. 1, but includes a thin metal ring 15 sandwiched between a lossless annular member 8 and a lossy annular member 9.

  FIG. 4a shows a cross section of the resonator of FIG. 3 and also shows the electric field and current (I) generated in the resonator in the TM110 mode. FIG. 4b is a plan view of the resonator. The TM110 mode is caused in the lossy annular member 9. A lossless annular member couples the pi-1 mode to a lossy annular member. The metal ring 15 has a smaller outer diameter than the ceramic annular member, thus allowing for improved magnetic coupling between the resonance of the lossy annular member and the flat annular member so that the pi-1 mode is as previously described. Will be attenuated. The TM110 current flows around the outer diameter of the ceramic and the metal ring does not disturb them. The pi-mode residual magnetic field is substantially reduced and can be brought to zero by the metal ring. The operation of the metal washer 15 is also shown in the graph of FIG.

FIG. 5 shows the depth of the pi mode fringe field and the pi-1 mode TM110 field to the resonator. The vertical axis 16 represents the position where the anode vane meets the resonator, and the vertical axis 17 represents the position where the resonator meets the pole piece. The vertical line 18 represents the position of the metal ring 15. The horizontal line 19 of this chart is a plot of the strength of the electric field generated in the pi-1 mode, and shows that these electric fields enter the resonator including the portion having a large loss. Therefore, a lossy ceramic can affect the residual electric field and attenuate it. Line 20 is a plot of the electric field strength generated in the pi mode. The field strength drops sharply when the electric field encounters a metal ring, so that only a small portion of the electric field enters the lossy part of the resonator.
Using the magnetron arrangement of FIG. 3, the pi-1 mode Q ₀ can be reduced from 1000 to nearly 50. However, the change in pi mode is negligible and the change in Q ₀ is from 1000 to approximately 950. This can be accommodated by slight adjustments to the magnetron operating system, which is within the scope of those skilled in the art.

The metal washer preferably has an outer diameter smaller than the annular members 8 and 9. This feature allows magnetic coupling between the lossy annular member and the lossless annular member. The metal ring can be realized in the form of a metal layer on one surface of the annular members 8, 9, or formed by metallizing both the upper annular member 9 and the lower annular member 8. Also good. Although the present invention has been described in the context of a multi-part resonator, the resonator may comprise a single part having different loss characteristics in different regions of the resonator.
A suitable ceramic for the resonator is alumina, but any insulator that is compatible with vacuum may be used. Since ceramic washers are mass-produced inexpensively, our solution to the problem of spurious radiation is low cost and simple. The cost of the resonator is typically a few pence, and the mounting of the resonator in the magnetron is not cumbersome, so there is no significant increase in manufacturing and labor costs.
Although the present invention was devised in connection with a low power magnetron, it is believed that it can be readily applied to high power magnetrons. Although the anode vane magnetron fixed with a normal strap has been described, the resonator can be used in combination with, for example, a rising sun type magnetron. Further modifications can be made without departing from the scope of the invention. For example, the dielectric resonator does not necessarily have an annular shape and does not necessarily have a closed shape. Furthermore, the dielectric resonator need not contact every blade.

1 is a cross-sectional view of a magnetron constructed in accordance with the present invention. It is a graph of the experimental data which shows the change of the electric field with respect to the position of pi mode and pi-1 mode of the magnetron of FIG. FIG. 6 is a cross-sectional view of another magnetron constructed in accordance with the present invention. It is sectional drawing of the resonator of FIG. FIG. 4 is a plan view of the resonator of FIG. 3. It is a graph of the experimental data which shows the change of the electric field with respect to the position of pi mode and pi-1 mode of the magnetron of FIG.

Claims (27)

A strap-fixed magnetron comprising an anode having at least one vane defining a plurality of cavities and a dielectric resonator, wherein a portion of the resonator is lossy and is adapted to absorb radiation, The other part of the resonator is substantially lossless and does not absorb radiation, the dielectric resonator is disposed adjacent to at least one of the vanes, and the resonator The strap-fixed magnetron is arranged to at least partially attenuate radiation generated during use in a predetermined mode of operation of the magnetron. A strap-fixed magnetron comprising an anode having a plurality of vanes defining a plurality of cavities and a dielectric resonator, wherein a portion of the resonator is lossy and absorbs radiation, said resonance The other parts of the resonator are substantially lossless and do not absorb radiation, the dielectric resonator is located adjacent to the vane, and the resonator is in use. A strap-fixed magnetron, characterized in that it is arranged to at least partially attenuate radiation generated in a predetermined operating mode of the magnetron.   3. The magnetron according to claim 1, wherein the predetermined mode is a pi-1 mode.   4. The magnetron according to claim 1, wherein the lossy portion of the resonator is disposed further away from the anode blade than the other portion. 5.   The magnetron according to any one of claims 1 to 4, wherein the lossy part of the resonator is thinner than the other part.   6. The magnetron of claim 5, wherein the lossy portion of the resonator has a thickness that is less than a quarter of the other portion.   The magnetron according to any one of claims 1 to 6, further comprising a conductive region sandwiched between the lossy portion and the other portion.   The lossy portion of the resonator is formed of a first annular member, the other portion is formed of a second annular member, and the first and second annular members are substantially coaxial. The magnetron according to any one of claims 1 to 6.   9. The magnetron according to claim 8, further comprising a third member made of a conductive material sandwiched between the first and second annular members.   The magnetron according to claim 9, wherein the third member has an annular shape and is substantially coaxial with the first and second members.   The magnetron according to any one of claims 1 to 10, wherein the dielectric resonator is made of a ceramic material.   The magnetron according to claim 11, wherein the ceramic material is alumina.   The magnetron according to claim 11 or 12, wherein the lossy portion is made of a ceramic material mixed with carbon.   14. A magnetron according to any one of the preceding claims, wherein the vanes are arranged around a common axis and the resonator is substantially coaxial with the vanes.   A radar system incorporating the magnetron according to any one of claims 1 to 14. Means for attenuating radiation generated by a strap-fixed magnetron in a predetermined mode of operation, said means comprising an anode having a plurality of vanes defining a plurality of cavities, a dielectric resonator, and a portion of the resonator Is lossy and adapted to absorb radiation, and other parts of the resonator are substantially lossless and do not absorb radiation, and the resonator is Means arranged to at least partially attenuate radiation generated in a predetermined operating mode of the magnetron.   The radiation attenuation unit according to claim 16, wherein the predetermined mode is a pi-1 mode.   18. The radiation attenuation means according to claim 16, wherein the lossy portion of the resonator is disposed further away from the anode blade than the other portion.   19. The radiation attenuation unit according to claim 17, wherein a lossy part of the resonator is thinner than the other part.   20. The radiation attenuation means of claim 19, wherein the lossy portion of the resonator has a thickness that is less than a quarter of the other portion.   The radiation attenuation unit according to any one of claims 16 to 20, further comprising a conductive region sandwiched between the lossy part and the other part.   The lossy portion of the resonator is formed of a first annular member, the other portion is formed of a second annular member, and the first and second annular members are substantially coaxial. The radiation attenuation means according to any one of claims 16 to 20.   The radiation attenuation means according to claim 22, further comprising a third member made of a conductive material sandwiched between the first and second annular members.   The radiation attenuation means according to claim 23, wherein the third member has an annular shape and is substantially coaxial with the first and second members.   The radiation attenuation means according to any one of claims 16 to 24, wherein the dielectric resonator is made of a ceramic material.   26. Radiation attenuation means according to claim 25, wherein the ceramic material is alumina.   27. The radiation attenuation means according to claim 26, wherein the lossy portion is made of a ceramic material mixed with carbon.

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