DE3240133A1 - Resonator, constructed as a waveguide section, for a travelling wave tube - Google Patents

Abstract

An improved damping resonator for a travelling wave tube is specified, which has a rectangular damping body in a waveguide section which is expanded in the shape of a box.

Description

description

Resonator designed as a waveguide section for a traveling wave tube The present invention relates to a waveguide section with a rectangular Cross-section formed resonator of a traveling wave tube with a ceramic Damping material that reduces the free cross-section of the waveguide.

Traveling wave tubes with waveguide sections in which damping bodies are arranged from ceramic are, for. B.

from DE-AS 12 92 762 and German Offenlegungsschriften 24 44 729 and 27 24 743 known. It also known from it, the damping body in the form of wedge-shaped ceramic parts with good thermal conductivity in the waveguide sections.

The good heat-conducting arrangement of such damping bodies in waveguide sections as well as complicated ones such as B.

Wedge-shaped damping bodies make the production of such Arrangements relatively difficult.

The present invention is therefore based on the object novel waveguide section with damping body for a traveling wave tube of the Specify the type mentioned at the beginning, which can be produced in a simplified manner and also a good reproducibility of the high-frequency behavior, especially with regard to unwanted reflections.

This object is achieved according to the invention in that the Clear height H of the waveguide section expanded to a clear height H1 and that a one-part or multi-part, rectangular, ceramic damping body is used with a thickness d such that H1-d applies C H = H2.

A major advantage of the invention is that the damping body can be produced in a simple geometric shape, namely in a rectangular shape are, whereby a high accuracy and thus a well-predictable high-frequency behavior can be reached.

In addition, the corresponding metallic waveguide walls can also be used simply and accurately produce, so that a good contact of the ceramic body with the subsequent waveguide walls is ensured, which is particularly advantageous for good heat dissipation from the damping bodies.

On the basis of the preferred exemplary embodiment shown in FIGS the invention is explained in more detail below.

FIG. 1 shows a longitudinal cross section and FIG. 2 shows a cross section by the width of a waveguide resonator according to the invention, as it is as a damping resonator is suitable for a traveling wave tube.

The essential embodiment of the invention is a box-like one Increase in the waveguide end, caused by a paragraph 6, in which a one or more part ceramic.Dämpfungskörper 2, 3 is, whose thickness d is greater than the depth of the box-like elevation, so that a corresponding edge 8 of the damping body 2, 3 opposes the incoming high-frequency wave. With In other words, it is very important that the one located above the damping body 2, 3 free height H2 is less than the free height H of the front waveguide section. The length of the damping body in the direction of the waveguide length depends on the geometrical and thermal conditions of the tube. The total height H1 of the extended waveguide part is composed of the thickness d of the damping body 2, 3 and the free height H2 above. The free height H of the waveguide part 1, which is coupled to the tube, is, as shown, larger than the free one Height H2. The height H2 is preferably about 80 to 40 as the free height H of the front Waveguide part 1.

According to a further preferred embodiment, there is the damping body from two ceramic parts 2 and 3, which preferably have a different damping value own, it being useful if the ceramic part adjacent to the waveguide end 9 2 has a higher damping value than the ceramic part 3 in front of it. Also in this case, both ceramic parts can be easily manufactured as rectangular bodies will.

From the cross section shown in Figure 2 it can be seen how through corresponding U-shaped design of the upper waveguide part 4 a definition of the ceramic body 3 can take place, namely in that the side wall of the upper Part 4 is made about thicker than the side wall of the lower part 7. The The protruding edge of the side parts of the upper part 4 press the ceramic part 3 then into the lower waveguide part 7. The connection of the two waveguide parts 4 and 7 at point 5 is expediently a solder seam connection.

Another embodiment provides in the free space over the ceramic body 2, 3 at a distance of k / 4 wavelength from the waveguide end 9 to provide a metallic projection 10 which acts as a kind of joint. This projection 10 preferably extends over the entire width of the waveguide.

Claims (7)

Claims As a waveguide section with a rectangular cross-section trained resonator of a traveling wave tube with a ceramic damping material, which reduces the free cross section of the waveguide, characterized in that the clear height H of the waveguide section (i) expands to a clear height H1 and that in the expansion space thus formed a one-part or multi-part, rectangular, ceramic damping body (2, 3) is used with such a% hen thickness d that we have H d (H = H2. 2. Resonator according to claim 1, characterized in that the thickness d of the damping body (2, 3) is chosen so large that the free height H2 90% to 20%, in particular 80% to 40% of the clear height H of the non-expanded waveguide part amounts to. 3. Resonator according to claim 1 or claim 2, characterized in that that the width of the waveguide section (1) is essentially unchanged and corresponds to the width of the damping body (2, 3) used. 4. Resonator according to one of claims 1 to 3, characterized in that that the damping body consists of two ceramic parts (2, 3) with different damping values consists. 5. Resonator according to claim 4, characterized in that the two Ceramic parts (2, 3) arranged one behind the other in the longitudinal direction of the waveguide and the ceramic part (2) with the higher attenuation value is the waveguide end (9) is arranged facing. 6. Resonator according to one of claims 1 to 5, characterized in that that in the free space between the damping body (2, 3) and the opposite Waveguide wall on this a metallic projection (10) about X / 4 wavelength is arranged away from the waveguide end (9). 7. Resonator according to one of claims 1 to 6, characterized in that that the expansion space formed by increasing the waveguide height from H to H1 essentially completely filled by the ceramic damping body (2, 3) is.