RU192642U1 - DOUBLE WAVE TEE - Google Patents

Abstract

The utility model relates to the radio industry and can be used in waveguide, antenna, and microwave measurement technology. The double waveguide tee contains H and E channel waveguides folded by a plug in the H-plane of the adjacent channel waveguides having a double section. The E-channel waveguide is oriented parallel to the H-plane of the H-channel waveguides and adjacent channels, orthogonal to their longitudinal axis, in addition, the E-channel waveguide is placed on the wide wall of the double section in such a way that it has a common wide wall with a gap in it. One end of the E-channel waveguide is shorted. To reduce the overall dimensions of the waveguide tee, without compromising the matching characteristics in the frequency range, when used in waveguide transmission lines made on the basis of a foil dielectric, two matching reflectors with a length of D> a / 2 and an angle of 135 are formed on the double section of the waveguides of adjacent channels ° <α <170 ° to the narrow walls of the waveguide of the H-channel and to the narrow walls of the waveguides of adjacent channels, respectively, where a is the size of the wide wall of the waveguides of adjacent channels. The waveguides of adjacent channels are located relative to each other at a distance of 0 <A <a. The waveguide of the E-channel is made in a plate made of a microwave dielectric folded on both sides with ε> 1, so that six reflectors are installed in the short-circuit region in pairs symmetrically with respect to the longitudinal axis of the waveguide E-channel. A short circuit, six reflectors and narrow walls of the waveguide E-channel are formed by rows of closely spaced through metallized holes having electrical contact with the foil layers, and the wide wall of the waveguide E-channel is the portion of the foil between the rows of metallized holes. The slot is made in the common wide wall of the region of the dual waveguide section and the E-channel waveguide at a certain distance from the short circuit, at the extension of the central axis of the H-channel waveguide, the short circuit, six reflectors and narrow walls of the E-channel waveguide do not intersect. On the opposite side of the slit to the wide wall of the doubled waveguide section on the extension of the central axis of the H-channel waveguide, there is a matching rectangular metal prism of height h <b, where b is the size of the narrow wall of the H-channel waveguide and adjacent channel waveguides. The technical result of the proposed solution is to reduce the overall dimensions of the waveguide tee, without compromising the matching characteristics in the frequency range, when used in waveguide transmission lines made on the basis of a foil dielectric. 4 silt

Description

The proposed utility model relates to the radio industry and can be used in waveguide, antenna and microwave measurement technology.

Known waveguide double tee [SU No. 1467624 A1 4 Н01Р 5/20, decl. 1987 and publ. 1989] containing a matching element in the form of a truncated pyramid with a metal pin located at the intersection of the shoulders, quarter-wave transformers installed in the E-shoulder and H-shoulder, an inductive diaphragm located in the E-shoulder, additionally, in order to expand the working band of frequencies, a metal plate having a T-shape and a thickness equal to (0.085-0.09) a, where a is the size of the wide wall of the shoulders, and located on the narrow walls of the E-shoulder and two side shoulders, the vertical part of the metal plate is introduced posted in e-shoulders e and has a length of λ / 8, and its horizontal part is located in the lateral shoulders and has a length of λ, where λ is the wavelength in the shoulders.

Known waveguide double tee [RU No. 184831 U1, decl. 2018 and publ. 2018], containing the waveguide H- and E-arms, waveguide lateral shoulders and a metal pin located in the region of their intersection, characterized in that the waveguide lateral shoulders and the waveguide H-arm are made in a plate made of a two-sided microwave dielectric with ε> 1, the narrow walls of the waveguide lateral shoulders and the waveguide H-arm are formed by rows of closely spaced through metallized holes having electrical contact with the foil layers, and the wide walls of the waveguide lateral shoulders and the waveguide H-arm are asth of the foil between the rows of metallized holes, while the waveguide E-arm is tightly adjacent to the wide walls of the waveguide lateral shoulders and the waveguide H-shoulder in the region of their intersection, the foil layer of which is the shorted end of the waveguide E-shoulder, and the wide walls of the waveguide E-shoulder are parallel narrow walls of the waveguide H-shoulder, and in the region where the waveguide E-shoulder adjoins the intersection of the waveguide lateral arms and the waveguide H-shoulder, a rectangular window is made that does not cross metallized s aperture, a length ₁ and a width b <a ±<b, ₁ where a size of the broad wall of the waveguide E-plecha, b-resolution E-plecha, narrow wall of the waveguide and waveguide E-plecha installed inside a dielectric liner with ε> 1 adjacent to the wide walls of the waveguide lateral arms and the waveguide H-arm in the region of their intersection.

The main disadvantages of these technical solutions are that the waveguide lateral shoulders are perpendicular to the waveguide H-input, the complexity of the design and not adaptability when used in waveguide transmission lines made on the basis of a foil dielectric.

The closest in nature is a double waveguide tee [RU No. 2366043 C1 H01P 5/20, decl. 2008 and publ. 2009] containing waveguides of H and E channels folded by a plug in the H plane, waveguides of adjacent channels having a common narrow wall and a double section, characterized in that the E-channel waveguide is oriented parallel to the H-plane of the H-channel waveguides and adjacent channels, orthogonal to their longitudinal axis, placed on the wide wall of the double section in such a way that it has a common wide wall with a half-wave gap in it, and one end of the E-channel waveguide is short-circuited.

The main disadvantages of these technical solutions are the design complexity and low technology when used in waveguide transmission lines made on the basis of a foil dielectric.

The essence of the proposed utility model is that the double waveguide tee contains waveguides of H and E channels, folded by a plug in the H-plane of the waveguides of adjacent channels having a double section. Moreover, the E-channel waveguide is oriented parallel to the H-plane of the H-channel waveguides and adjacent channels, is orthogonal to their longitudinal axis, in addition, the E-channel waveguide is located on the wide wall of the double section in such a way that it has a common wide wall with a slot in it . One end of the E-channel waveguide is shorted.

New features of the proposed double waveguide tee are that two matching reflectors, length D> a / 2, located at an angle of 135 ° <α <170 ° to the narrow walls of the H-channel waveguide and to the narrow walls of the waveguides, are formed on the doubled section of the waveguides of adjacent channels adjacent channels, respectively, where a is the size of the wide wall of the waveguides of adjacent channels. The waveguides of adjacent channels are located relative to each other at a distance of 0 <A <a. The waveguide of the E-channel is made in a plate made of a microwave dielectric folded on both sides with ε> 1, so that six reflectors are installed in the short-circuit region in pairs symmetrically with respect to the longitudinal axis of the waveguide E-channel. A short circuit, six reflectors and narrow walls of the waveguide E-channel are formed by rows of closely spaced through metallized holes having electrical contact with the foil layers, and the wide wall of the waveguide E-channel is the portion of the foil between the rows of metallized holes. The slot is made in the common wide wall of the region of the dual waveguide section and the E-channel waveguide at a certain distance from the short circuit, at the extension of the central axis of the H-channel waveguide, the short circuit, six reflectors and narrow walls of the E-channel waveguide do not intersect. A matching rectangular metal prism of height h <b, where b is the size of the narrow wall of the H-channel waveguide and adjacent channel waveguides, is located on the wide wall of the double waveguide section opposite the slot from the center of the H-channel waveguide;

The technical result of the proposed solution is to reduce the overall dimensions of the waveguide tee, without compromising the matching characteristics in the frequency range, when used in waveguide transmission lines made on the basis of a foil dielectric.

In FIG. 1 shows an example of a double waveguide tee.

In FIG. Figure 2 shows a graph of the standing wave coefficient (SWR) of waveguide channels versus frequency (Δf).

In FIG. Figure 3 shows a plot of the division between the input waveguides of the H and E channels and the waveguides of adjacent channels on the frequency (Δf).

In FIG. Figure 4 shows a plot of the isolation between the input waveguides of the H and E channels and the waveguides of adjacent channels on the frequency (Δf).

The double waveguide tee consists of a foil dielectric plate 1, waveguides of adjacent channels 3 and 4, and an H-channel waveguide 5. An E-channel waveguide 6, a short circuit 7 of the E-channel waveguide, and reflectors 11 ÷ 16 are made in the foil dielectric 1 plate. Matching reflectors 8, 9 and matching metal prism 2 are placed on the double section of the waveguides of adjacent channels 2. A slot 10 is made in the wide wall of the double section of the waveguides of adjacent channels 3, 4 so that the short circuit 7, six reflectors 11 ÷ 16 and narrow walls do not intersect 17 waveguide E-channel 6.

The principle of operation of the proposed double waveguide tee is as follows: the microwave signal received in the waveguide of the E-channel 6 is divided in half between the waveguides of adjacent channels 3, 4 and does not enter the waveguide of the H-channel 5. The signals at the outputs of the waveguides of adjacent channels 3, 4 have the opposite phase. In-phase division of the microwave signal between the waveguides of adjacent channels 3, 4 is carried out upon excitation of the waveguide of the H-channel 5, while the waveguide of the E-channel 6 is decoupled. The isolation of the waveguide of the E-channel 6 and the waveguide of the H-channel 5 is achieved due to the symmetrical arrangement of the slot 10 with respect to the waveguide of the H-channel 5, and the isolation of the waveguides of adjacent channels 3, 4 is determined by the level of coordination of the waveguide of the H-channel 5 and the waveguide of the E-channel 6. The level of coordination of the waveguide of the E-channel is determined by the choice of certain sizes and relative position slots 10, short circuit 7, reflectors 11-16, as well as the choice of certain sizes and the angle of inclination to the narrow walls of the H-channel waveguide matching reflectors 8, 9. The level of matching of the H-channel waveguide is determined by the choice of certain sizes and angle of inclination to the narrow walls of the waveguide H - channel matching reflectors 8, 9, as well as the size and location of the matching metal prism 2 in the region of intersection of the waveguides of adjacent channels 3.4 and the waveguide of the H-channel.

The results of the practical implementation of the proposed technical solution are not in doubt. Experimental samples of double waveguide tees of various sections were manufactured and tested.

Claims (1)

A double waveguide tee comprising H and E channel waveguides folded by a plug in the H-plane of adjacent channel waveguides having a double portion, the E-channel waveguide oriented parallel to the H-plane of the H-channel waveguides and adjacent channels, orthogonal to their longitudinal axis, in addition the E-channel waveguide is placed on the wide wall of the double section in such a way that it has a common wide wall with a gap in it, and one end of the E-channel waveguide is short-circuited, characterized in that on the double section of the waveguides two matching reflectors are formed, of length D> a / 2, located at an angle of 135 ° <α <170 ° to the narrow walls of the H-channel waveguide and to the narrow walls of the adjacent channel waveguides, respectively, where a is the size of the wide wall of the adjacent channel waveguides moreover, the waveguides of adjacent channels are located relative to each other at a distance 0 <A <a, while the waveguide of the E channel is made in a plate made of a microwave dielectric foil on both sides with ε> 1, so that six matching reflectors are installed in the short-circuit region in pairs but relative to the longitudinal axis of the waveguide E-channel, the short circuit, six reflectors and narrow walls of the waveguide E-channel are formed by rows of closely spaced through metallized holes having electrical contact with the foil layers, and the wide wall of the waveguide E-channel is the foil section between the rows of metallized holes , the slot is made in the common wide wall of the region of the double waveguide section and the E-channel waveguide at a certain distance from the short circuit, at the center the short axis, six matching reflectors and narrow walls of the E-channel waveguide do not intersect the axis of the H-channel waveguide, while a matching rectangular metal prism of height h <b is located on the continuation of the central axis of the H-channel waveguide, opposite the slot from the wide wall of the double waveguide section where b is the size of the narrow wall of the waveguide of the H-channel and waveguides of adjacent channels.

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