DE2424010A1 - Ninety-degree H-plane waveguide bend - has corner reflector of specified set-back to reduce insertion loss - Google Patents

Abstract

The 90 deg. H-plane waveguide bend consists of a piece of rectangular waveguide bent through 90 deg. in the plane containing its larger faces. The corner so-formed has a 45 Deg. reflector (S) to reduce the bend's insertion loss. The reflector is set back from the actual corner by a distance d equal to 0.35a, where a is the width of the guide. The set-back reflector reduces miss-match and effectively increases the bend's bandwidth. Earlier types of bend with the reflector cutting straight across the corner, i.e. along the dotted line, give poorer matches.

Description

Waveguide angle bent over the broad side The present one Invention is concerned with a waveguide angle bent over the broad side with a bevel acting as a mirror in the corner to reduce the adjustment error.

Waveguide elbows have a little mismatch when you look at yours Selects the radius of curvature large enough. However, this is often not the case for device designs possible because of the space required for this. A direct kink in a waveguide into a desired angle causes a non-negligible mismatch, because the resulting sack represents a significant mismatch. The mismatch is reduced significantly by chamfering a corner, because the deflection the field lines is facilitated. What is important is that the angle is relative to the two incoming waveguide symmetrically is arranged.

Corners formed in this way are not ideal in terms of their properties.

You still have an often not negligible mismatch, which can be improved by attaching a dielectric overlay to the mirror can, but the bandwidth of the transmission is limited. If not complete Bevelling of the corner can also cause the mismatch in a very narrow frequency range be reduced.

The object of the invention was to improve the bandwidth of the transmission and to reduce the mismatch of the elbow.

According to the invention this object is achieved in that the mirror is offset parallel to the outside, the mirror retains its dimensions. Optimal Transfer properties are achieved by using the offset d = 0.35 the waveguide width dimensioned.

In this way it was possible to improve the transmission properties of a Waveguide angle broadband with the smallest mismatch a smooth waveguide very close.

The invention is based on an exemplary embodiment with the aid of the drawing described in more detail.

In Fig. 1 of the drawing is a waveguide angle with the long Side a shown in plan view according to the invention and in Fig. 2 a diagram with different displacement values of the mirror to the outside, where the reflection factor is plotted over the normalized frequency.

Fig. 1 shows the top view of a folded over the broad side Waveguide angle of rectangular cross-section with the large side a. The dashed Line gives the. complete bevel acting as a mirror in the angle state of the art again. The distance d is the amount by which the mirror is parallel is offset outward while maintaining the dimensions of the mirror.

In Fig. 2 is the diagram of the arrangement according to the invention Fig. 1 reproduced. The calculated frequency response is dependent on the outward displacement of the mirror; Measuring points are for the parameters d = 0.24a and d = 0.35a are entered. They are plotted against the normalized frequency f / fc, where fc means the cutoff frequency of the fundamental wave of the waveguide, left the input standing wave ratio VSWR as the ordinate and the right as the ordinate Reflection factor in dB with adaptation at the output. From this you can see that the cheapest Value for the outward displacement is at d = 0.35a. This indicates the curve for the value d = 0.35a. With this offset of the mirror is the broadest angle. With the value d = 0.35a one gets the cheapest Field distribution in the elbow of a waveguide with a rectangular cross-section.

Claims (2)

Claims Waveguide angle bent over the broad side with one as a mirror effective bevel in the corner to reduce the adjustment error, characterized in that the mirror (S) is offset parallel to the outside, the mirror (S) its Maintains dimensions. 2. waveguide angle according to claim 1, characterized in that the offset is d = 0.35 of the waveguide width (a). L e r s e i t e