RU2808442C1 - Waveguide rotating joint - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: waveguide rotating joint consists of two transitions from a rectangular waveguide with wave H10 to round waveguides with wave E01, which are movably articulated through a choke. The transitions from a rectangular waveguide with wave H10 to a round waveguide with wave E01 are made in such a way that pairs of rectangular waveguides, which are the outputs of waveguide double T-bridges folded into a fork in the E-plane, are symmetrically connected to the ends of the round waveguides. Absorbers are installed in the total arms of the waveguide double T-bridges.

EFFECT: reduction in the level of signal modulation that occurs when the rotor rotates relative to the stator, a reduction in ohmic losses per pass, the elimination of resonances that lock the rotating joint, a reduction in VCSW at the joint input, and an increase in the operating efficiency of a radar station with a rotating antenna device.

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Description

The invention relates to microwave technology and can be used to create broadband rotating joints for radar stations with a rotating antenna device.

Waveguide rotating joints have found wide application in the waveguide paths of various antennas operating from centimeter waves to millimeter waves. There are a large number of such rotating joints described in the literature. In particular, an important class of waveguide rotating joints is a waveguide rotating joint, consisting of two waveguide-coaxial transitions, movably coupled along a coaxial line with the TEM wave [1 - Centimeter wave transmission lines. Translation from English edited by Remeza G.A. Volume 2, 1951, Sov. radio, 342 p., p. 43], [2 - Markov G.T. Antennas. 1960, Gosenergoizdat, 535 p.], [3 - Harvey A.F. Ultrahigh frequency technology. Volume 1, 1965, Sov. radio, 783 p., p. 182], [4- Patent US 2784383, Zaleski J.F. Microwave guide rotary joint]. The disadvantages of this type of waveguide rotating joint are the limitation of the average microwave power in the coaxial line and the difficulty of implementation in the millimeter wave range.

Another approach for implementing a waveguide rotating joint is to use the lowest axisymmetric wave of a circular waveguide - the E01 wave. Most of these rotating joints consist, as a rule, of two transitions from a rectangular waveguide with an H1010 wave to a round waveguide with an axisymmetric E01 wave, differing in adjustment elements (tuning) [1-3], [5 - Patent US 2584399, Preston W.M. Rotatable wave guide joint]. These junctions are connected to each other by round waveguides using a choke. One of the transitions is stationary (stator), the second is movable (rotor), rotating together, for example, with the antenna. At the junction of rectangular waveguides with round waveguides, along with the required wave E01, a parasitic wave H11 is excited in the round waveguide. At the same time, as practice shows, resonances can occur in the operating frequency band, leading to an increase in losses, which is a disadvantage. To eliminate them, it is necessary to reduce the longitudinal size of the rotating joint, which causes difficulties in implementing the drive, or to use special methods to suppress the H11 wave [1-3], which leads to different designs of rotating joints. In particular, to suppress the H11 wave, a resonant ring installed in a circular waveguide and a special absorber (for example, a resonator with absorbing material connected to a stationary circular waveguide through four longitudinal slits) are used. The specified elements for suppressing the H11 wave are resonant, which limits the operating frequency band.

The closest technical solution for the same purpose to the claimed invention in terms of the combination of features is a rotating joint [6- US Patent 5442329, Ghosh Subir, Da Silva L.C. Waveguide rotary joint and mode transducer structure therefor], adopted as a prototype, in which the transition from a rectangular waveguide with wave H10 to a circular waveguide with an axisymmetric wave E01 is made in such a way that the axisymmetric wave E01 in the circular waveguide is excited by two rectangular slits (rectangular waveguides), to which the H-tee plug on a rectangular waveguide with wave H10 is connected. The waves coming from the input rectangular waveguide and propagating in the two arms of the rectangular waveguide H-tee have the same phase. Since both paths along the rectangular waveguide arms to the center of the circular waveguide are the same, the circular waveguide will be excited by a symmetrical field, which theoretically should not contain H11 waves. The known rotating joint consists of two such transitions from a rectangular waveguide with wave H10 to a round waveguide with axisymmetric wave E01, connected by a choke.

The reasons preventing the achievement of the technical result indicated below when using this known device include the fact that in the known device, as a result of manufacturing errors, the symmetry of the excitation of the circular waveguide is broken, and H11 waves are excited in it. This leads to the appearance of “blocking” resonances at some frequencies of the operating band of the rotating joint, when microwave power is not transmitted from input to output, but is reflected and, to a lesser extent, absorbed in the walls of the waveguides. The excitation of the H11 wave in a circular waveguide is also the cause of modulation in the known design when the rotor rotates relative to the stator, since at the output there is interference of signals along the E01 and H11 waves.

An important indicator of the quality of any waveguide rotating joint is the voltage standing wave ratio (VSWR) at the joint input. A low level of standing wave ratio is especially important for the waveguide rotating joint in the transmission channel path. Another important indicator of the quality of a waveguide rotating joint is the microwave power loss per pass, which must be minimized. An important indicator of the quality of a waveguide rotating joint is the modulation of the output signal when the rotor rotates relative to the stator.

The proposed waveguide rotating joint, consisting of two transitions from a rectangular waveguide with wave H10 to a round waveguide with wave E01, movably coupled along round waveguides through a choke, solves the problem of ensuring a low level of modulation of the output signal when the rotor rotates relative to the stator, ensuring low ohmic losses per passage , completely eliminating resonances that “lock” the rotating joint, ensuring low VSWR at the joint input.

To solve the proposed technical problem, a waveguide rotating joint is proposed, consisting of two transitions from a rectangular waveguide with wave H10 to round waveguides with wave E01, movably articulated through a choke (throttle connection). According to the invention, transitions from a rectangular waveguide with wave H10 to a round waveguide with wave E01 are made in such a way that pairs of rectangular waveguides are symmetrically connected to the ends of the round waveguides, which are the outputs of waveguide double T-bridges folded with a fork in the E-plane [3, p. 171 ], in the total arms of which absorbers are installed.

The proposed technical solution is aimed at obtaining a technical result, expressed in achieving a low level of modulation of the output signal when the rotor rotates relative to the stator, in achieving low ohmic losses per pass, in completely eliminating resonances that “lock” the rotating joint, in achieving low VSWR at the joint input.

In fig. Figure 1 shows an embodiment of the proposed waveguide rotating joint (for illustration, sections of the throttle connection are shown).

In fig. Figure 2 shows the internal channel of the waveguides for the proposed waveguide rotating joint (the bearing is not shown).

In fig. 3, the waveguide rotating joint is shown for clarity in a state where the transitions from a rectangular waveguide with wave H10 to a round waveguide with wave E01 are disconnected from the circular waveguide (the internal channel of the waveguides is shown).

The following notations are used in the figures:

1 - round waveguide;

2 - transition from a rectangular waveguide with wave H10 to a round waveguide with wave EO1;

3 - throttle connection;

4 - input in the form of a rectangular waveguide;

5 - matched loads (absorbers).

The waveguide rotating joint contains a circular waveguide (1) and two identical transitions from a rectangular waveguide with wave H10 to a circular waveguide with wave E01 (2), connected to both ends of the circular waveguide (1). The circular waveguide (1) consists of coaxially installed movable and fixed sections, connected to each other by means of a throttle connection (3). Each transition from a rectangular waveguide with wave H10 to a circular waveguide with wave E01 (2) has an input in the form of a rectangular waveguide (4), the axis of which is directed perpendicular to the axis of the circular waveguide (1). Transitions from a rectangular waveguide with wave H10 to a round waveguide with wave E01 (2) are made in the form of waveguide double T-bridges folded with a fork in the E-plane, connected to the round waveguide (1) in such a way that both output rectangular waveguides of the bridge are located symmetrically in end wall of the circular waveguide (1). Matched loads (absorbers) (5), which can be made in the form of wedges of absorbing material, are installed at the inputs of the summary channels of the bridges, directed coaxially with the round waveguide (1). A possible design of wedges in matched loads (absorbers) (5) is shown in Fig. 2 and 3. The inputs of the difference channels of waveguide double T-bridges, folded with a fork in the E-plane (hereinafter referred to as “waveguide double T-bridges”), are the inputs of the waveguide rotating joint.

The device works as follows.

The input of the waveguide rotating joint receives a signal with a frequency whose value is in the operating frequency band. At the outputs of the waveguide double T-bridge in the cross section of its junction with the circular waveguide (1), an odd (antiphase) amplitude excitation is realized, shown in Fig. 3. This signal is supplied to excite a circular waveguide (1). As a result, an axisymmetric wave E01 is excited in the circular waveguide (1), which propagates through the throttle connection (3) into the second section of the circular waveguide (1), where it arrives at the junction with the second double T-bridge, excites the same odd amplitude distribution there and ultimately arrives at the difference arm of the second double T-bridge. With the ideal symmetry of manufacturing double T-bridges folded with a fork in the E-plane, with such excitation of round waveguides (1), there is fundamentally no excitation of the H11 wave. However, as a result of manufacturing errors, the excitation symmetry of the circular waveguide (1) is broken, and H11 waves are excited in it.

In the proposed waveguide rotating joint, the excitation of HI 1 waves does not lead to the appearance of “blocking” resonances at some frequencies of the operating band of the waveguide rotating joint, since the power of the H11 waves enters the matched loads (absorbers) (5) installed in the total arms folded with a fork in E- planes of double T-bridges.

The absence of “blocking” resonances at some frequencies of the operating band also means that the VSWR characteristic will not contain narrow peaks at which there will be high VSWR values. The resulting VSWR characteristic will have a fairly smooth character, which is the result of the interference of the characteristics of both waveguide double T-bridges.

In the proposed waveguide rotating joint, the H11 wave is excited in a circular waveguide (1) only as a result of technological manufacturing errors leading to violation of symmetry. In the proposed design of the waveguide rotating joint, the H11 waves are absorbed in the matched loads of the total arms of the double T-bridges, which virtually eliminates the interference of the output signals along the E01 and H11 waves and allows minimizing the modulation of the output signal when the rotor rotates relative to the stator.

The proposed design of a waveguide rotating joint can be implemented at centimeter and millimeter wavelengths. The operating frequency band in the proposed design of the waveguide rotating joint is limited both by the operating frequency range of the waveguide double T-bridge and by the frequency range from the EO1 wave cutoff to the exit from the H21 wave cutoff in the circular waveguide (1).

Thus, the above information indicates that, when using the claimed invention, the following set of conditions is fulfilled:

- a waveguide rotating joint embodying the claimed invention is intended for use in industry, namely in microwave technology, for example, as a rotating joint for radar stations with a rotating antenna device;

- for the claimed device in the form as it is characterized in the independent claim of the stated claims, the possibility of its implementation using the means described in the application has been confirmed;

- a waveguide rotating joint, embodying the claimed invention, makes it possible to implement the following technical result: to obtain a rotating joint with a low level of modulation of the output signal when the rotor rotates relative to the stator, with low ohmic losses per passage, with the complete elimination of resonances that “lock” the rotating joint, with low VSWR at the joint input, which will ensure efficient operation of the radar station with a rotating antenna device.

Claims (1)

Waveguide rotating joint, consisting of two transitions from a rectangular waveguide with wave H10 to round waveguides with wave E01, movably articulated through a choke, characterized in that the transitions from a rectangular waveguide with wave H10 to a round waveguide with wave E01 are made in such a way that to the ends Round waveguides are symmetrically connected to pairs of rectangular waveguides, which are the outputs of waveguide double T-bridges folded with a fork in the E-plane, in the total arms of which absorbers are installed.