JP2016152069A - Coaxial magnetron - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coaxial magnetron which allows high-duty-ratio pulse driving and can suppress frequency drift.SOLUTION: A coaxial magnetron has a structure in which heat generated in the vicinity of a negative electrode 1 is released via a heat dissipation member 15 arranged in a tuning shaft 11. The heat dissipation member is fixedly arranged in a tuning box 10 via a buffer member 16. As a result, even if the heat dissipation member is thermally expanded, the heat is released by keeping thermal contact with a tuning arm 12. This structure prevents heat stress from being transmitted to the tuning arm.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a structure of a magnetron that oscillates microwaves, and in particular, a coaxial magnetron having an external coaxial cavity outside an anode resonant cavity.

  Conventionally, magnetrons have been used in various devices because they can oscillate high-power microwaves efficiently with a simple structure. For example, a radar device that performs detection by changing the frequency of a microwave, or a linac device that obtains a high-energy electron beam by injecting a microwave into a linear accelerator needs to be tuned precisely. For this reason, a coaxial magnetron that can easily change the oscillation frequency and has stable operation has been used.

FIG. 5 is an explanatory diagram of a conventional coaxial magnetron. As shown in FIG. 5, vanes 2 serving as anodes arranged radially are joined to an anode cylinder 3 around a cathode 1 arranged in the center, and the anode resonance cavity 50 is formed by the vanes 2 and the anode cylinder 3. Is formed. An external coaxial cavity 60 that is coaxial with the anode resonant cavity 50 is formed between the anode cylinder 3 and the cylindrical side surface 5. Here, anode resonant cavity 50 and external coaxial cavity 60 are coupled in a high frequency manner. Specifically, by providing every other slot 4 on the anode cylinder 3 with respect to the vane 2, the high frequency electromagnetic field of the anode resonant cavity 50 oscillated in the π mode is generated in the TE ₀₁₁ mode in the external coaxial cavity 60. Resonates at. An input side structure 7 connected to the input unit 6 and an upper structure 8 connected to the tuning box 10 are arranged above and below the anode resonant cavity 50 and the external coaxial cavity 60, so that the cathode 1 Pole pieces 9a and 9b are arranged on the upper and lower sides, respectively.

  Further, by adjusting the tuning shaft 11 attached to the tuning box 10 up and down, the position of the tuning piston 13 disposed in the external coaxial cavity 60 is moved up and down via the tuning arm 12, so The oscillation frequency of the magnetron can be adjusted by changing the resonance frequency of the body 60.

  In such a configuration, when oscillating a high-power microwave with a peak output of several MW class and an average output of several kW class, it is necessary to cool the heat generated at the anode. Cooling is performed by providing a cooling passage 11 in the side structure 7 and a cooling passage 14 in the upper structure 8 and flowing a cooling liquid. This type of coaxial magnetron is described in Patent Document 1.

  In this type of coaxial magnetron, the cooling characteristics of the vane 2 are improved by cooling from the input side structure 7 and the upper structure 8, and the duty of pulse driving is improved even at a high output where the peak output is several MW. Operation up to a ratio of about 0.001 is possible.

  On the other hand, as the operating state becomes higher in output and higher in duty ratio, a phenomenon called frequency drift occurs. This is because the temperature around the joint between the tuning shaft 11 and the tuning arm 12 rises mainly due to radiation via the pole piece 9b, and thermal expansion occurs in the tuning shaft 11 and the tuning arm 12, and the tuning piston 13 This is a phenomenon that occurs because the position moves downward in the drawing.

  Here, since the oscillation frequency of the coaxial magnetron is dominantly determined by the resonance frequency of the external coaxial cavity 60, the downward movement of the tuning piston 13 in the drawing increases the oscillation frequency of the magnetron. Further, since the cooling passage 14 is provided in the vicinity of the anode cylinder 3, it is necessary to make the tuning arm 12 long, which is a factor for increasing the frequency drift.

  Therefore, the cooling passage 14 is not formed in the upper structure 8, and a cooling passage is formed in the tuning piston 13 from the tuning shaft 11 through the tuning arm 12 to flow the cooling liquid. Although it can be suppressed, this system is a movable part, and a narrow and long cooling passage must be formed, which makes the structure very complicated.

  In addition, since the anode is cooled only by the cooling passage 11, it is necessary to suppress the duty ratio to a low level, specifically, about 0.0002 to 0.0008 for high power oscillation of several MW class with peak power.

JP, 2014-165032, A

  When the conventional coaxial magnetron is oscillated with a peak power of several MW class, by providing the cooling passage 14 in the upper structure 8, the duty ratio can be increased to about 0.001, but there is a problem of frequency drift. Could not be resolved. On the other hand, if an attempt is made to form a cooling passage in the tuning piston 13 from the tuning shaft 11 via the tuning arm 12 in order to suppress the frequency drift, the cooling passage 14 cannot be provided in the upper structure 8 and the duty is changed. There was a problem that the ratio had to be kept as low as 0.0002 to 0.0008. An object of the present invention is to provide a coaxial magnetron that solves these problems, has a high pulse drive duty ratio, and can suppress frequency drift.

  In order to achieve the above object, an invention according to claim 1 of the present application includes: an anode resonant cavity that joins a vane to an anode cylinder disposed around a cathode; and an external coaxial cavity provided outside the anode cylinder. An input side structure and an upper structure are joined to both ends of the anode resonant cavity and the external coaxial cavity, and the anode resonant cavity and the external coaxial cavity are coupled in a high frequency manner by a slot. In the coaxial magnetron that adjusts the resonance frequency by adjusting the tuning piston arranged in the external coaxial cavity, and adjusting the tuning arm and the tuning shaft that support the tuning piston to move the position of the tuning piston, Forming at least a cooling passage through which the coolant flows in the upper structure, and in the tuning shaft, Characterized in that it is arranged a heat radiating member joined to the arm.

  The invention according to claim 2 of the present application is the coaxial magnetron according to claim 1, wherein a heat shielding plate is provided between the cathode and the upper structure.

  The coaxial magnetron of the present invention cools the vicinity by flowing a cooling liquid through a cooling passage provided in the upper structure, and at the same time heats generated in the central part of the coaxial magnetron near the cathode. It is structured to dissipate heat to the outside through a heat dissipating member provided inside, and it becomes possible to suppress and control thermal stress deformation of the tuning shaft and the tuning arm. As a result, it is possible to increase the duty ratio of the pulse drive and effectively suppress the frequency drift even in the high output operation of several MW class.

  The heat dissipating member of the present invention has a coaxial structure with a gap so as not to be inscribed inside the tuning shaft, and can be easily manufactured and assembled by being made of a material having higher heat conductivity than the tuning shaft. There is an advantage that the manufacturing cost is not increased.

  In addition, the present invention has a structure including a heat shielding plate between the cathode and the upper structure, thereby reducing the heat radiation received in the vicinity of the tuning axis, thereby preventing saturation of the heat dissipation capability of the heat dissipation member. Thus, the frequency drift amount can be surely suppressed.

It is explanatory drawing of the coaxial magnetron of the 1st Example of this invention. It is a figure explaining the frequency drift suppression effect of this invention. It is explanatory drawing of the coaxial magnetron of the 2nd Example of this invention. It is explanatory drawing of the coaxial magnetron of the 3rd Example of this invention. It is explanatory drawing of this kind of conventional coaxial magnetron.

  The coaxial magnetron of the present invention has a structure in which a coolant flows through a cooling passage provided in the upper structure, cools the vicinity thereof, and generates heat generated in the central portion of the coaxial magnetron in the vicinity of the cathode 1. The structure is such that heat is radiated via a heat radiating member 15 provided in the tuning shaft 11. Since this heat radiating member is fixedly arranged in the tuning box 10 by the buffer member 16, even if the heat radiating member 15 is thermally expanded, it keeps heat contact with the tuning arm 12 while radiating heat to the outside. The structure does not transmit thermal stress to the tuning arm 12. As a result, the temperature rise of the tuning shaft 11 and the tuning arm 12 is suppressed, and the frequency drift can be suppressed.

  Further, by providing a heat shielding plate 17 between the cathode 1 and the tuning arm 12, the heat radiated from the cathode 1 can be shielded and the temperature rise of the tuning shaft 11 and the tuning arm 12 can be suppressed. Is possible. Examples of the present invention will be described in detail below.

  FIG. 1 is an explanatory diagram of a coaxial magnetron according to the first embodiment. As shown in FIG. 1, vanes 2, which are radially arranged anodes, are joined to an anode cylinder 3 around a cathode 1 arranged at the center, and an anode resonant cavity 50 is formed by the vanes 2 and the anode cylinder 3. Is formed. The anode cylinder 3 is provided with a slot 4. An external coaxial cavity 60 that is coaxial with the anode resonant cavity 50 is formed between the anode cylinder 3 and the cylindrical side surface 5. An input side structure 7 and an upper structure 8 connected to the input unit 6 are arranged above and below the anode resonant cavity 50 and the external coaxial cavity 60, so that pole pieces 9a, 9b is arranged.

  Further, by adjusting the tuning shaft 11 attached to the tuning box 10, the position of the tuning piston 13 disposed in the external coaxial cavity 60 is moved via the tuning arm 12, and the resonance of the external coaxial cavity 60 is achieved. By changing the frequency, the oscillation frequency of the magnetron can be adjusted. The tuning box 10 and the tuning arm 12 are connected by a metal bellows, and the anode resonant cavity 50 and the external coaxial cavity 60 are kept in a vacuum.

  The coaxial magnetron of this embodiment differs from the conventional example shown in FIG. 5 in that the anode cylinder 3 has a structure in which the upper cylinder 8 is bonded to the upper structure 8 by soldering so that the thermal resistance is minimized and the coolant flowing in the cooling passage 14 The anode is effectively cooled. By adopting such a structure, the cooling effect of the anode is increased, and even when the output is high such that the peak output is several MW class, the duty ratio of the pulse drive exceeds 0.001 and the operation to about 0.002 is possible. It becomes possible.

  On the other hand, the tuning shaft 11 has a hollow structure, and is arranged so as to have a coaxial structure with a gap so that the heat radiating member 15 is not inscribed inside the tuning shaft. The heat radiating member 15 is made of a material having higher heat conductivity than the tuning shaft 11. As shown in FIG. 1, since one end portion of the heat dissipation member 15 is disposed in the tuning box 10 by a buffer member such as an oxygen-free copper thin plate processed into an accordion shape, the internal heat is transferred to the outside by heat conduction. Can be released. Further, the heat dissipation member 15 itself contributes as a heat radiator. The heat radiating member 15 is not limited to a circular rod-like structure. Grooves can be formed on the surface to increase the surface area and improve heat dissipation characteristics. Here, the heat dissipation member 15 can increase the heat dissipation effect by using a high heat conductive material such as an oxygen-free copper rod or a heat pipe.

  In the coaxial magnetron of this embodiment configured as described above, the temperature rise near the junction between the tuning arm 12 and the tuning shaft 11 is suppressed. As a result, the temperature rise of the tuning shaft 11 is suppressed, and the thermal expansion of the tuning shaft 11 itself is suppressed. Further, since the temperature of the tuning piston 13 is relatively higher than the vicinity of the joint between the tuning shaft 11 and the tuning arm 12, the tuning arm 12 is displaced by thermal stress in the upward direction of the drawing, and cancels the thermal expansion of the tuning shaft 11. It becomes possible to reduce the frequency drift.

  FIG. 2 is a diagram comparing the frequency drift amount of the oscillation frequency of the conventional coaxial magnetron and the frequency drift amount of the oscillation frequency of the coaxial magnetron of the present embodiment. In this example, it can be seen that the frequency drift is reduced to about 1/6. In addition, it is found that after the operation time of about 15 minutes, it is thermally stable and a slight frequency drift amount is kept constant, so that the effect of the present invention is great.

  Next, a second embodiment will be described. As described above, in order to reduce the frequency drift, it is effective to reduce the temperature rise in the vicinity of the junction between the tuning shaft 11 and the tuning arm 12. Therefore, as shown in FIG. 3, it is also effective to arrange a heat shielding plate 17 that blocks heat in a path through which heat is radiated from the cathode 1 to the tuning arm 12. As the heat shielding plate 17, for example, a nickel thin plate, an iron thin film, or a tantalum thin film can be used.

  The third embodiment is a modification of the heat dissipation member 15. As shown in FIG. 4, it is possible to increase the heat dissipation effect by expanding the area of the tip of the heat dissipation member 15. At the same time, the temperature increase of the tuning shaft 11 itself is suppressed by separating the joint portion of the tuning shaft 11 and the tuning arm 12 from the central portion where the temperature is relatively high, thereby achieving a structure of suppressing the frequency drift amount.

1: cathode, 2: vane, 3: anode cylinder, 4: slot, 5: cylindrical side surface, 6: input section, 7: input side structure, 8: upper structure, 9a, 9b: pole piece, 10: Tuning box, 11: Tuning shaft, 12: Tuning arm, 13: Tuning piston, 14 cooling passage, 15: Heat radiation member, 16: Buffer member, 17: Heat shielding plate

Claims (2)

An anode resonant cavity that joins a vane to an anode cylinder disposed around a cathode; and an external coaxial cavity provided outside the anode cylinder; the anode resonant cavity and the external coaxial cavity An input-side structure and an upper structure are joined to both ends, and the anode resonant cavity and the external coaxial cavity are coupled with each other at a high frequency by a slot, and a tuning piston disposed in the external coaxial cavity includes: In the coaxial magnetron that adjusts the resonance frequency by moving the position of the tuning piston by adjusting the tuning arm and the tuning shaft that supports the tuning piston,
A coaxial magnetron characterized in that at least a cooling passage for flowing a coolant through the upper structure is formed, and a heat radiating member to be joined to the tuning arm is disposed in the tuning shaft. The coaxial magnetron according to claim 1,
A coaxial magnetron comprising a heat shielding plate between the cathode and the upper structure.

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