WO2018052335A1

WO2018052335A1 - Flexible circular corrugated single-mode waveguide

Info

Publication number: WO2018052335A1
Application number: PCT/RU2017/000139
Authority: WO
Inventors: Эдуард Александрович АЛЬХОВСКИЙ; Владимир Юрьевич БОРОНОВ
Original assignee: Эдуард Александрович АЛЬХОВСКИЙ; Владимир Юрьевич БОРОНОВ
Priority date: 2016-09-14
Filing date: 2017-03-17
Publication date: 2018-03-22
Also published as: DE212017000216U1; RU2626055C1

Abstract

The invention relates to microwave technology, and more particularly to high-frequency energy transmission lines, preferably in the Ku, Ka, Q, U and E bands. The present flexible, corrugated single-mode waveguide is in the form of a pipe made of an electrically conductive material and having a circular cross-section and annular corrugations along the longitudinal axis of the waveguide. The dimensions of the pipe are selected in the ranges: 0.785>R/λн>0.95; 0.354>а/λн>0.38; 0.524>Т/λн>0.533; 0.2>b/T>0.5; where R is the maximum outside radius of the pipe; λн is the wavelength corresponding to the low frequency of the single-mode band for the ЕН₁₁ mode; а is the corrugation depth; Т is the period of a corrugation; and b is the width of a corrugation at half of its depth. The technical result of the claimed invention is that of reducing loss and increasing the permissible strength of the transmitted signal by comparison with regular single-mode rectangular and circular waveguides, while also providing a dual-polarized mode of propagation of an ЕН₁₁ working wave and maintaining the flexibility of the waveguide.

Description

FLEXIBLE ROUND CORrugated single-mode waveguide

The invention relates to microwave technology, and in particular to transmission lines 5 of high-frequency energy, preferably in the ranges of Ku, Ka, Q, U, E.

Known round diaphragm waveguide (Parini CG, Clarricoats PJ B., Olver AD Single-mode operation of low-attenuation corrugated waveguide. Electronic Letters. 1977, v.13, Ns 1, pp. 16-17), which is a straight circular metal a pipe, inside of which are located annular diaphragms. When choosing certain ratios of the geometric dimensions of the structural elements of such a waveguide, an impedance structure is formed in it, which ensures the propagation of a hybrid wave of the UNC in a single-mode regime with anomalously small losses.

However, based on such a waveguide, it is impossible to create a flexible feeder

15 tract.

The closest analogue of the claimed invention is a technical solution known from the article (Alkhovsky E.A., Ilyinsky A.S. Numerical studies of the propagation constants of symmetric waves in a round corrugated waveguide. Radio engineering and electronics. 1979, vol.

20 XXIV, pp. 1684-1685) and US Pat. No. 4,429,290. This solution is a round corrugated flexible waveguide with a smooth corrugation shape for propagating the ΤΕοι fashion.

However, such a waveguide cannot be used as a bipolarization waveguide.

25 The technical problem to which the claimed invention is directed is to create a flexible round corrugated waveguide with a smooth nature of changing the transverse dimensions along the longitudinal axis and with a ratio of sizes that provide, along with the required mechanical characteristics, a single-mode propagation mode of a hybrid UNC wave with low losses.

The technical result of the claimed invention is to reduce losses while increasing the allowable power of the transmitted signal compared with regular single-mode rectangular and round waveguides while ensuring the bipolarization mode of propagation of the working wave of the UNC and while maintaining the flexibility of the waveguide.

The specified technical result is achieved due to the fact that in the flexible round corrugated single-mode waveguide, which is a pipe 5 made of conductive material of circular cross section with annular corrugations located along the longitudinal axis of the waveguide, the pipe dimensions are selected within:

0.785 <R / AH <0.95;

0.354 <a / An <0.38;

SE 0.524 <T / An <0.533;

0.2 <b / 7 ^" <0.5;

where R is the outer maximum radius of the pipe;

An is the wavelength corresponding to the lower frequency of the single-mode range

15 a - depth of the corrugation;

G - the corrugation period;

b is the width of the corrugation at half its depth.

For these values of the geometrical parameters of the corrugated waveguide in the operating wavelength range from An to Av, corresponding to the lower 20 and upper boundaries of the single-mode range, the only propagating mode is EEC.

The essence of the invention is illustrated using figures 1-8, which depict:

in FIG. 1 is a longitudinal section of the inventive waveguide;

25 in FIG. 2 - dependences of the overlap coefficient and the values of the geometric parameters of the waveguide normalized to the maximum boundary wavelength of the single-mode range, on the value of LT

in FIG. 3 - dependence of the normalized attenuation coefficient on the value of b / T;

in FIG. 4 shows the results of calculating the phase coefficient β and the attenuation coefficient a for an example of the design of waveguide A;

in FIG. 5 shows the results of calculating the phase coefficient β for an example of the design of waveguide B; in FIG. 6 shows the results of calculating the phase coefficient β for an example of the design of waveguide B;

in FIG. 7 - calculation results of the phase coefficient β for an example of the waveguide design at a / R = 0.3; T / R = 0.34; b / T = 0.2;

in FIG. 8 shows the results of calculating the phase coefficient β for an example of the waveguide design at a / An = 0.46; T / R = 0.71; b / Τ = 0.2.

The mechanical characteristics of the corrugated waveguide depend on b / Τ, i.e. flexibility, technological limitations in production, etc., and its electrical parameters, i.e. critical frequencies and locking frequencies of wave types, values of their phase and attenuation coefficients, etc.

Presented in FIG. 3 dependences of the normalized attenuation coefficient to the upper and lower wavelengths at frequencies that limit the single-mode mode, and at a frequency corresponding to the minimum value of the attenuation coefficient show that the attenuation coefficient decreases as the corrugation shape approaches the rectangular. A decrease in the attenuation coefficient can be achieved by reducing the frequency range.

For the example of FIG. Figures 4, 5 and 6 show the results of calculating the phase coefficient β of several types of waves and the attenuation coefficient a of the ЕН ^ wave type for a round corrugated waveguide with geometric dimensions corresponding to the three options (A, B, C).

In FIG. 4 shows the results of the calculation of option A.

The absolute dimensions of the waveguide correspond to the values: R = 5.0 mm, 7 = 3.34 mm, a = 2.25 mm at b / Τ = 0.2, which corresponds to the relative sizes R / AH = 0.785, Шн = 0.524, and / An = 0.353 for the lower frequency of the single-mode band fa = 47.1 GHz. From the graph (Fig. 4) it can be seen that there is a frequency band from fa = 47.1 GHz to fe = 50.63 GHz, within which the only propagating type of wave is the EEC. The damping coefficient σ of the EEC wave in the single-mode frequency range varies from 0.8 dB / m at fa = 47.7 GHz to 0.6 dB / m at a frequency fe = 50.05 GHz. For comparison, the attenuation coefficient σ of the Nu wave in a single-mode rectangular waveguide of the WR-22 type is 1.6 dB / m at a frequency of fa = 47.7 GHz and 1.15 dB / m at a frequency of fe = 50.05 GHz.

In FIG. 5 shows the results of calculating option B.

s The absolute dimensions of the waveguide correspond to the values: R = 5.0 mm, T = 3.34 mm, a = 2.25 mm at b / Τ = 0.2, which corresponds to the relative sizes R / AH = 0.785, T / An = 0.524 , a / An = 0.354 for the lower frequency of the single-mode range n = 47.7 GHz. From n = 47.7 GHz to fe = 51, 27 GHz, the ENC wave propagates in a single-mode mode.

In FIG. 6 shows the results of the calculation of option B.

The absolute dimensions of the waveguide correspond to the values: R = 5.0 mm, T = 2.8 mm, a = 2.0 mm at b / Τ = 0.5, which corresponds to the relative sizes R / AH = 0.95, T / An = 0.533, a / An = 0.38 for the lower frequency of the single-mode band, n = 52.04 GHz. Within the frequency band from I / N = 52.04 GHz to fe = 56.35 GHz, the only propagating wave type is EEC

With corrugation parameters lying outside the declared intervals of the geometrical dimensions of the waveguide, the ECC wave propagates either in a multimode mode, as, for example, in the case at R = 5.0 mm, Г = 1.7 mm, and a = 1.52 mm at b / Τ = 0.2, which corresponds to the relative dimensions a / R = 0.3 and T / R = 0.34 (Fig. 7), or as, for example, with R = 5.0 mm, T = 3.55 mm, a = 2.3 mm at b / T = 0.2, which corresponds to the relative sizes a / An = 0.46 and T / R = 0, 71 (Fig. 8), the ENT wave propagates in a narrow frequency range with high level of linear losses.

The inventive device can be manufactured as follows.

A tube of conductive material: metal, an alloy of several metals, a bimetallic composition or conductive plastic in the corresponding matrix undergoes hydroforming, due to which the tube takes on a given shape. The workpiece receives the required geometric dimensions, providing the properties of a flexible round corrugated single-mode waveguide.

Claims

Claim

Flexible corrugated single-mode waveguide, which is a pipe of conductive material of circular cross section with annular corrugations located along the longitudinal axis of the waveguide, characterized in that the pipe dimensions are selected within:

0.785> R / Ln> 0.95;

0.354> a / en> 0.38;

0.524> T / An> 0.533;

0.2> b / r> 0.5; where R is the outer maximum radius of the pipe;

An is the wavelength corresponding to the lower frequency of the single-mode range for the UNC mode;

а - corrugation depth;

T - the period of the corrugation;

b is the width of the corrugation at half its depth.