RU2211508C2 - Coaxial-to-waveguide adapter - Google Patents

Abstract

FIELD: microwave radio engineering. SUBSTANCE: proposed adapter that can function as matched coaxial-line-to-round-waveguide adapter has coaxial line section installed on its butt-end wall with certain displacement of their symmetry axes and coupler in the form of central conductor extension that incorporates longitudinal, inclined, and vertical parts as well as jumper, their values being matched with λ₀,; newly introduced are adjusting components. EFFECT: simplified design; ability of adjusting adapter power characteristics in waveguide frequency range. 2 cl, 1 dwg _

Description

 The invention relates to microwave technology and can be used as a coordinated transition from a coaxial line to a circular waveguide.

 Known coaxial transition from the waveguide to the line with the T-wave (A.S. 675495), containing a segment of a rectangular waveguide, to the end wall of which is connected a segment with a T-wave and a quarter-wave excitation element.

 A disadvantage of the known transition is that it satisfactorily operates under conditions of a limited difference in wave impedances between the segments of the waveguide and the line with the T-wave.

 Known coaxial waveguide transition (A.S. 879686, prototype and base object), containing cascade-connected segment of a coaxial transmission line, an intermediate coaxial section and a segment of a circular waveguide filled with a dielectric, in which a coupling element in the form of a longitudinal metal plate is placed.

 A disadvantage of the known transition is the design complexity and the absence of tuning elements that provide variations in the electrical characteristics of the transition in a wide frequency range.

 The aim of the invention is to simplify the design of the coaxial-waveguide transition and to enable the tuning of its characteristics in a wide frequency range.

 This goal is achieved by the fact that the coaxial line is connected to the end wall of the circular waveguide with an offset relative to the longitudinal axis of the waveguide, the communication element is made in the form of a conductor, which is a continuation of the central conductor of the coaxial line and closed on the longitudinal wall of the waveguide. In addition, tuning elements located in the plane of the communication element are introduced into the transition.

 As for the evidence of the materiality of the differences, within the framework of the materials accessible to the authors, no signs were found that are similar to the distinguishing features of the claimed object.

 The essence of the technical solution of the invention is illustrated by the drawing, which shows a General view of the coaxial waveguide transition, which converts the wave of the TEM of the coaxial line into the wave of the TE11 circular waveguide.

 The coaxial waveguide transition contains in a static state a segment of the coaxial line 1 mounted on the end wall 2 of the circular waveguide 3. The coaxial line 1 through the coupling element 4 in the form of a conductor, which is a continuation of the central conductor 5 of the coaxial line, is closed to the longitudinal wall of the waveguide 3. Communication element equipped with a jumper 6. A tuning screw 7 is installed between the end wall 2 and the jumper 6. Additionally, tuning screws 8. are installed at the output of the waveguide segment. The screws 7 and 8 are located in the plane of the element enta communication.

 The proposed device (see drawing) works as follows.

The TEM wave of the coaxial line 1 is converted into the TE11 wave of the circular waveguide 3 by means of a coupling element 4 made in the form of a conductor, which is a continuation of the central conductor 5 of the coaxial line 1 and consisting of a longitudinal (relative to the axis of the waveguide 3), inclined and vertical parts. The angle of inclination depends on the ratio λ ₀ / D and is specified experimentally.

The total length of longitudinal and inclined portions connecting element is equal to λ _0/2, where λ ₀ - wavelength in free space, wherein the vertical part is inductive load end of the inclined portion, which provides radiation input coaxial line 1, the electromagnetic wave energy TEM in the upper half-round waveguide 3 and its simultaneous conversion into a TE11 wave of a circular waveguide.

The total length of the longitudinal portion, the inclined portion to the jumpers and jumpers 6 is also equal to λ _0/2, which provides a cut-off wavelength of TEM and its complete conversion to the TE11 wave.

 The vertical part of the coupling element and the jumper introduce the inductive component of the reactance of the coupling element, which compensates for the capacitive component of the longitudinal and inclined parts. The final adjustment of the communication element is carried out using screw 7.

The displacement of the axis of the coaxial line l ₁ relative to the axis of the circular waveguide 3 provides for the transformation by the coupling element 4 of the wave impedances of the coaxial line and the circular waveguide. It was experimentally established that the magnitude of the displacement, as well as the length of the longitudinal part of the coupling element, is l ₁ = l ₂ = 0.1D, where D is the diameter of the circular waveguide.

The coupling element is closed to the longitudinal wall of the circular waveguide at a distance of l ₃ = 0.21λ _in , where λ _in is the TE11 wavelength in the circular waveguide from the end wall 2.

Additional adjustment screws 8 are arranged at a distance l ₄ = 0.28λ _in from the end wall 2. Screws 8 provide offset adjustment coaxial-waveguide transition in the direction of lower frequency.

 Unlike the prototype, the design of the proposed device is simpler and provides the possibility of tuning the coaxial waveguide transition in a wide frequency range.

Claims (1)

1. Coaxial waveguide transition containing a segment of a coaxial transmission line, a segment of a circular waveguide and a communication element closed to the longitudinal wall of a circular waveguide, characterized in that the segment of a coaxial line is mounted on the end wall of a circular waveguide, the communication element is made in the form of a continuation of the central conductor of the coaxial line and contains a longitudinal relative to the axis of the waveguide inclined and vertical parts and a jumper mounted on the lower side of the communication element, while the length of the longitudinal part ra the magnitude of the displacement of the coaxial line relative to the axis of the circular waveguide and is equal to 0.1D, where D is the diameter of the waveguide; overall length of longitudinal and inclined portions is λ _0/2, where λ ₀ - length of the waveguide in free space; the total length of the longitudinal portion, the inclined portion to the jumpers and jumpers are λ _0/2, wherein the axis of the coaxial line, a circular waveguide, the coupling element and the web are in one plane, wherein in the waveguide wall mounted adjusting screws, two of which are located in the lower part of the waveguide wall at a distance of 0.1 and 0.28λ _in , and one in the vertical part of the waveguide wall at a distance of 0.28λ _in from the end wall of the waveguide, where λ _in is the TE11 wavelength, and the coupling element is closed to the bottom by its vertical part the waveguide wall standing 0.21λ _in .
2. Coaxial waveguide transition according to claim 1, characterized in that the angle between the axes of the inclined part of the coupling element and the circular waveguide is 26-30 ^o .