JPH047551Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] This invention relates to a straight-beam microwave tube such as a multi-cavity klystron or a traveling wave tube, and particularly relates to improvement of the collector electrode portion thereof.

[Technical background of the invention and its problems] For example, a pulse oscillation multi-cavity klystron used in a radar device employs a natural air cooling or forced air cooling structure. A klystron with a very high operating frequency band has a small collector electrode, and a pole piece and a permanent magnet are arranged to surround this collector electrode. This impedes heat dissipation from the collector electrode, and the collector electrode is likely to be heated during long-term operation.

[Purpose of the invention] This invention provides a beam straight microwave tube that can enhance the heat dissipation effect of the collector electrode and ensure stable operation.

[Summary of the invention] In this invention, a space is formed between the collector electrode placed downstream of the high-frequency action section and a cylindrical pole piece with a bottom surrounding the collector electrode, and a ventilation hole communicating with this space is formed in the pole piece. This is a straight-beam microwave tube formed in one piece. This creates a cooling path in which air passes through the outer periphery of the collector electrode and circulates to the outside air from the ventilation hole formed in the pole piece, allowing relatively efficient air cooling. Therefore, overheating of the collector electrode and permanent magnet is suppressed, and stable operation is achieved.

[Embodiments of the invention] Examples of the invention will be described below with reference to the drawings. Note that the same parts are represented by the same symbols.

FIGS. 1 and 2 show an example of a multi-cavity klystron with a linear electron beam for pulse oscillation. A high frequency acting section 11 is located downstream of the beam of an electron gun section (not shown).
is located. In this high frequency acting section 11, a plurality of resonant cavities 12 and drift tubes 13 are arranged in series, and an electron beam can travel therein. A bottomed cylindrical pole piece 14 is joined to the downstream end of the beam. The pole piece 14 is made of a ferromagnetic material such as iron and has a beam passage hole formed at the bottom, and has a circular outer peripheral surface. And inside this pole piece,
A bottomed cylindrical collector electrode 15 made of a metal material with good thermal conductivity such as copper is arranged. That is, the open end 15a of the collector electrode 15 is hermetically sealed to the bottom 14a of the pole piece 14, and the collector electrode bottom 15b in which the fixing screw hole is formed extends close to the opening 14b of the pole piece. A frame-shaped permanent magnet 16 for electron beam focusing is magnetically connected to the outer peripheral surface of the pole piece 14 .

Now, the collector electrode 15 has an outer dimension smaller than the inner diameter of the pole piece 14, thereby forming a cylindrical space 17 therebetween. There are four ventilation holes 18 in the middle of the pole piece 14.
are perforated radially and communicate with the inner space 17. Further, between the outer peripheral shoulder near the collector electrode end 14b and the inner peripheral shoulder of the pole piece 14,
A spacer 20 having a plurality of ventilation holes 19 is tightly fitted to connect the two in a thermally conductive manner. This spacer 20 is desirably made of a material with good thermal conductivity such as copper or aluminum.

A klystron with such a structure is, for example, incorporated into a radar device and operated.
When the collector electrode is used horizontally as shown in the figure, the outside air passes from each ventilation hole 18 through the outer peripheral space 17 of the collector electrode as shown by the dotted arrow in the figure, and then to the other ventilation holes 18, Naturally circulates outside air through 19. Further, even when the collector electrode is used vertically, air enters through each ventilation hole and circulates to the outside through the ventilation hole of the spacer.
Of course, it may be operated with forced air cooling. The spacer also provides heat conduction from the collector to the pole piece, and the spacer mechanically and stably fixes the collector electrode and the pole piece to each other.

[Effects of the invention] As explained above, in this invention, the cylindrical pole piece coaxially surrounds the entire axial length of the collector electrode, and a space is formed between these pole pieces and the collector electrode, and this space is A plurality of ventilation holes communicating with the pole piece are formed radially in a part of the high-frequency action part side of the pole piece, and a plurality of axial ventilation holes are further formed between the tip of the collector electrode and the inner circumferential wall of the pole piece. An aluminum spacer is interposed for heat transfer.

As a result, the collector electrode, which is buried inside the cylindrical pole piece, is inserted between the tip of the collector electrode and the inner circumferential wall of the pole piece through the radial ventilation hole formed on the high-frequency action side of the pole piece. Cooling is achieved by the cooling air flowing through the axial ventilation holes of the provided spacers, and the heat conduction and dissipation to the pole pieces by the spacers having high thermal conductivity, such as copper or aluminum, are also added for efficient cooling. Moreover, the collector electrode is mechanically stably held on the pole piece by this spacer. In this way, stable operation is obtained.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal cross-sectional view of a main part showing an embodiment of this invention, and FIG. 2 is a side view taken at 2-2 in FIG. 1. 11... High frequency action part, 14... Pole piece, 15... Collector electrode, 16... Permanent magnet,
17... Space, 18, 19... Ventilation hole, 20...
Spacer.

Claims (1)

[Claims for Utility Model Registration] A collector electrode is arranged downstream of the high-frequency action part, a cylindrical pole piece made of ferromagnetic material is arranged surrounding this collector electrode, and a frame-shaped permanent magnet is attached to the pole piece. In the beam straight microwave tube configured such that the collector electrodes are connected to each other and cooling air is circulated in the space around the collector electrodes, the cylindrical pole piece coaxially surrounds the entire axial length of the collector electrodes, and The above-mentioned space is formed between these pole pieces and the collector electrode, and a plurality of ventilation holes communicating with this space are formed radially in a part of the high-frequency action section side of the above-mentioned pole piece. 1. A straight-beam microwave tube characterized in that a spacer made of copper or aluminum having a plurality of axial ventilation holes is interposed between the pole piece and the inner circumferential wall of the pole piece for heat transfer.