SU862278A1 - Waveguide resonator - Google Patents

Description

The invention relates to microwave technology. A waveguide resonator is known that contains a segment of a rectangular waveguide with inductive pins arranged symmetrically with respect to the longitudinal axis, and tuning elements mounted in the middle of the wide wall of the section of a rectangular waveguide, one of which is in the form of a stepped dielectric, which is installed with the ability to move along its axis 1. However, this resonator has a complex structure and large dimensions. The purpose of the invention is to simplify the design and reduce the size. To do this, in a waveguide resonator containing a segment of a rectangular waveguide with inductive pins arranged symmetrically relative to the longitudinal axis, and tuning elements installed in the middle of the wide wall of a segment of a rectangular waveguide, one of which is designed as a step dielectric pin installed with displacements along the Jew axis, inductive pins and tuning elements are placed in the same cross-sectional plane of the rectangular waveguide segment, and the other tuning element The t is made in the form of a metal screw, while the tuning elements are placed in opposite walls of the rectangular waveguide segment and are connected to one another by means of a threaded joint having a greater pitch and reverse thread direction in comparison with the threaded joint of the metal screw with a wide wall of a rectangular piece a waveguide, one of the steps of the dielectric pin facing the wide wall of a segment of a rectangular waveguide in which it is placed, is made in the shape of a truncated cone with a smaller m in the plane of the base wall. The drawing shows the structure of a waveguide resonator. The waveguide resonator contains a segment 1 of a rectangular waveguide with inductive arrays 2 arranged symmetrically with respect to the longitudinal axis, and tuning elements in the form of a stepped dielectric pin 3 mounted for movement along its axis, and in the form of a metal screw 4, while inductive Pin 2 and tuning elements are placed in the same plane of the cross section of segment 1 of a rectangular waveguide, the tuning elements are placed in the middle of its opposite wide walls and are connected one with d using a threaded joint 5, which has a larger pitch and reverse thread direction in comparison with the threaded joint b of a metal screw 4 with a wide wall of a segment 1 of a rectangular waveguide, and one of the steps of the dielectric pin 3 facing the wide wall in which it is placed, made in fox le truncated cone with a smaller base in the plane of this wall.

Waveguide resonator works as follows.

In the initial position, the metal screw 4 is immersed by about 1/3 in length 1 of the rectangular waveguide, ensuring at this position the matching of the entire waveguide resonator at the center frequency, i.e. the compensation value of the inductances of the pins 2.

In subsequent positions, upon further immersion of the metal screw 4, the value of the capacitance introduced by it increases, but the inductance value of the pins 2 also increases, as the stepped dielectric pin 3 leaves the cavity of section 1 of the rectangular waveguide, thereby bringing together the pins 2 .

The need for faster removal from the cavity of section 1 of a rectangular waveguide of a stepped dielectric pin 3, than the introduction of a metal screw 4 into it, is dictated by the fact that the capacitance when the screw 4 is immersed increases faster than the inductance. This is ensured by the fact that the metal screw 4 has in the cavity of a segment 1 of a rectangular waveguide a threaded connection 5 with a stepped dielectric pin 3 of greater pitch and reverse direction in comparison with the threaded connection b.

The need for the conical part of the dielectric pin 3 is determined by the nonlinear law of capacitance change introduced by the metal screw 4, for which it is necessary to provide a similar change in the inductance of the pins 2,

I Thus, when the metal screw 4 is immersed, both the absolute value of the capacity of this screw and the value of the inductance of the pins 2 at the same time increase, which, provided they are equal in absolute value, ensures that the average tuning frequency is preserved and the loaded Q-factor of the waveguide resonator changes,

BALNODOD. The resonator has smaller dimensions than the prototype (the entire waveguide resonator is made in one section of a 1-square rectangular waveguide) and a simpler design (one step dielectric pin instead of

three, whereby the adjustment mechanism is much easier);

Claims (1)

1. USSR author's certificate 589836, cl. H 01 R 1/20, 1976 (prototype).