RU53073U1 - DIPLEXER - Google Patents

Abstract

The utility model relates to microwave technology and allows you to reduce losses in the passband of the frequency channels of the diplexer, spurious passband, increase the isolation between the passband of the frequency channels of the diplexer, which contains a segment of the waveguide 1, made in the form of hollow cylinders 2 with external threads 3 located on them the ends, the second hollow cylinders 4 with internal threads 5 at their ends, the input coaxial connector 6 orthogonal to the cylindrical wall 7 of the hollow cylinder 2, wall 8 with an opening 9, price a conductor 10 of the input connector 6 located in the hole 9, cylindrical dielectric resonators 11, communication loops 12 and 13 with input 14 and 15 resonators 11, respectively, of the first 16 and second 17 filters, the penultimate 18 and last 19 cylinders at the ends of the waveguide 1 on each side from the connector 6, the holes 20 formed at the intersection of the surfaces of the cylinders 18 and 19, the extreme end wall 21, the coaxial resonators 22 formed by the conductive rods 23 on the end walls 24 of the extreme cylinders 2, screws 25 of the resonance clock tuning elements the frequency of the resonators 11 installed in the penultimate cylinders 2 in the end walls 26 parallel to the end walls of the resonators 11, the conductive screws 27 for setting the resonant frequency of the resonators 22, each installed coaxially to the conductive rod 23 on the extreme walls 21 of the extreme cylinders 2, the screws 28 for adjusting the connection between the resonators 11, installed in the penultimate cylinders 2, and resonators 22, connectors 29 are installed each orthogonally to the walls 30 of the extreme cylinder 2. Connectors 6 and 31 are connected to the transmission lines of the microwave circuit. In the presence of an electromagnetic wave in the line, the communication loops 12 and 13 excite electromagnetic oscillations at the resonant frequencies of the respective resonators 14 and 15, which transmit electromagnetic energy at the corresponding frequencies to the coaxial resonators 22.

Description

The utility model relates to microwave technology and is intended to create frequency separation devices based on open disk dielectric resonators mainly in the decimeter and long wavelengths of the centimeter wavelength range.

Known diplexers (see Dielectric resonators in microwave microelectronics / Yu.M. Bezborodov, L.G. Gassanov, A.A. Lipatov, etc. - Reviews on Electronic Engineering, Series 1 "Microwave Electronics", issue 4 (786) , Central Research Institute "Electronics" MEP USSR, 1981, 82 pp. 53-56), which contain two segments of the waveguide, transcendent in the working frequency range of the diplexer, in which bandpass filters on dielectric resonators are made, Y-circulator, to two of the three outputs of which the inputs of the pass-pass filters are connected, and the third output of which and the outputs of the band-pass filters OSCAL filters constitute output terminals of the device.

However, such technical solutions have additional bandwidth losses introduced by the Y-circulator.

Closest to the proposed one is a diplexer (see. Dielectric resonators in microwave microelectronics / Yu.M. Bezborodov, L. G. Gassanov, A. A. Lipatov, etc. - Reviews on Electronic Engineering, Series 1 “Microwave Electronics, vol. 4 (786), Central Research Institute "Electronics" MEP USSR, 1981, p. 56, fig. 46), containing a segment of a cylindrical waveguide of circular cross section with end walls and a metal wall with a hole orthogonal to its cross section, which performs the function of an extraordinary screen in the working strip frequencies in which the Y-circulator is located, the first shoulder of which It is connected to an input coaxial connector with a central conductor mounted orthogonally relative to the cylindrical wall of a segment of a cylindrical waveguide, and its second and third shoulders are connected to communication loops with input cylindrical

dielectric resonators of two pod-pass filters formed each by dielectric resonators coaxially placed along the axis of a circular cylindrical waveguide segment on one or the other side of the Y-circulator and reinforced by axisymmetric holders, and the output dielectric resonators of the filters are electromagnetically connected each to output coupling elements connected with output coaxial connectors of its channel.

However, such diplexers have additional losses associated with the use of the Y-circulator.

The technical task of the proposed utility model is to reduce losses in the passband of the frequency channels of the diplexer and spurious passband, increase the isolation between the passband of the frequency channels of the diplexer.

The solution to this problem is achieved by the fact that the known diplexer containing a segment of a round cylindrical waveguide with extreme end walls, an input coaxial connector mounted orthogonally relative to the cylindrical wall of a segment of a cylindrical waveguide, a communication loop with input cylindrical dielectric resonators of the first and second band-pass filters formed each cylindrical dielectric resonators coaxially located along the axis of a segment of a circular cylindrical the ducts on one and the other sides of the input coaxial connector with a central conductor and mounted therein by axisymmetric holders, and the output cylindrical dielectric resonators of the first and second band-pass filters are electromagnetically connected to output communication elements connected to the output coaxial connectors of the first and second frequency channels, and a metal wall with a hole orthogonal to the cross section of a segment of a circular cylindrical waveguide, equipped with intermediate wires yaschimi walls with connection holes,

second metal end walls, additional conductive rods, tuning elements for resonant frequencies of cylindrical dielectric resonators, tuning elements for resonant frequencies of coaxial resonators, tuning elements for communication between open dielectric and coaxial resonators, all tuning elements are made in the form of screws, a section of a circular cylindrical waveguide is made of hollow metal cylinders with external threads located at their ends, and second hollow metal cylinders with internal threads located at their ends, all hollow metal cylinders are threaded and form an external cylindrical screen, the input coaxial connector is located orthogonally relative to the external cylindrical surface of the hollow metal cylinder, the metal wall is installed in the cross section of the hollow metal cylinder passing through the axis of symmetry of the input coaxial connector, the hole in the metal wall is located at the inner cylindrical surface of the hollow metal cylinder at the installation location of the input coaxial connector, the central conductor of the input coaxial connector is located in the hole in the metal wall parallel to its plane, and the communication loops with the input cylindrical dielectric resonators of the first and second bandpass filters, respectively, are connected to the central conductor of the input coaxial connector and are located parallel to the plane of the metal wall on its opposite sides, moreover, forming the penultimate and last one cylinder at the ends of the external cylindrical screen on each side of the input coaxial connector are arranged orthogonally in the holes formed at the intersection of the cylindrical surfaces are arranged intermediate conductive wall, coinciding with the surface of the penultimate hollow metal cylinders, hollow metal cylinders terminal screen configured

the second metal end walls, in each of the penultimate hollow metal cylinders, an additional end wall is installed, in each of the last hollow metal cylinders there is an additional rod forming a coaxial resonator and mounted on the second metal end wall of the extreme hollow metal cylinder, tuning elements for the resonant frequencies of cylindrical dielectric resonators installed in the penultimate hollow metal cylinders, the screws of which are located in The additional end walls parallel to the end walls of the cylindrical dielectric resonators, the screws for tuning the resonant frequency of the coaxial resonators, are installed each coaxially to the conducting rod on the extreme end walls of the extreme hollow metal cylinders, the screws for adjusting the communication between the open disk dielectric resonators and the coaxial resonators are located in the penultimate hollow metal cylinders and in the communication holes in the intermediate conductive walls of the penultimate and last single hollow metal cylinders, output coaxial connectors, each installed orthogonally relative to the cylindrical wall of the extreme hollow metal cylinder.

In addition, the communication loop with the input cylindrical dielectric resonator of the first band-pass filter can be performed with a length equal to half the wavelength at the resonant frequency of the input cylindrical dielectric resonator of the first band-pass filter, and the communication loop with the input cylindrical dielectric resonator of the second band-pass filter made with a length equal to half the wavelength at the resonant frequency of the input cylindrical dielectric resonator of the second strip -transmission filter.

Additionally, the communication loop can be made in the form of conical spirals.

In addition, the axisymmetric holders of each cylindrical dielectric resonator are made in the form of three thin metal plates, the planes of which are oriented along the radius of the hollow metal cylinders and are turned at an angle of (120 ± 10) ° relative to each other, while one of the ends of each of the thin metal plates abuts into the cylindrical surface of the dielectric resonator, and the opposite end of this thin metal plate is fixed relative to the inner surface of the hollow metal cylinder ndra.

In addition, the elements of communication with the coaxial resonator can be made in the form of flat communication loops.

Additionally, the outer surface of the second hollow metal cylinders can be made in the form of flat radiators,

The essence of the utility model is illustrated by drawings, in which Fig. 1 shows a diplexer on dielectric resonators, and Fig. 2 shows a view of AA, Fig. 3 shows a view along arrow B of a diplexer solution element, Fig. 4 shows a view B of a diplexer technical solution element, figure 5 shows a view along arrow C of the solution element of the diplexer, figure 6 shows a view C of the solution element of the diplexer, figure 7 shows a view of the current sample of the diplexer, figure 8 shows the frequency response of the diplexer.

The diplexer contains a segment of a cylindrical waveguide 1, which serves as a screen, which is made in the form of hollow metal cylinders 2, equipped with external threads 3 located at their ends, second hollow metal cylinders 4 with internal threads 5 located at their ends, input coaxial connector 6, mounted orthoganally relative to the cylindrical wall 7 of the hollow metal cylinder 2, the metal wall 8 with the hole 9, the Central conductor 10 of the input coaxial connector 6, placed in the hole and 9, cylindrical

dielectric resonators 11, communication loops 12 and 13 with input 14 and 15 cylindrical dielectric resonators 11, respectively, of the first 16 and second 17 band-pass filters, the penultimate 18 and last 19 cylinders at the ends of a section of a cylindrical waveguide 1 on each side of the input of coaxial connector 6 of the diplexer , holes 20 formed at the intersection of the cylindrical surfaces of the hollow metal cylinders 18 and 19, the extreme end wall 21, coaxial resonators 22 formed by conductive rods 23, reinforced on the second metal end walls 24 of the extreme hollow metal cylinders 2, screws 25 of the tuning elements of the resonant frequencies of the cylindrical dielectric resonators 11 installed in the penultimate hollow metal cylinders 2 in the end walls 26 parallel to the end walls of the cylindrical dielectric resonators 11, the conductive screws 27 of the tuning of the resonant frequency of the coaxial resonators 22, each installed coaxially with the conductive rod 23 on the extreme end walls 21 of the extreme hollow metal cylinders 2, nti 28 communication settings between the cylindrical dielectric resonators 11 installed in the penultimate hollow metal cylinders 2 and the coaxial resonators 22, coaxial connectors 29 for communication with the supply lines, each installed orthogonally relative to the cylindrical wall 30 of the extreme hollow metal cylinder 2. Central conductors 31 of the coaxial connectors 29 for communication with the supply lines are connected to communication elements 32 with coaxial resonators 22, which are installed in the last hollow metal x cylinders 19 of the first and second bandpass filters. Cylindrical dielectric resonators 11 mounted in hollow metal cylinders 2 with axisymmetric holders 33.

Communication loops 12 and 13 can be made in the form of conical spirals.

The axisymmetric holders 33 of each cylindrical dielectric resonator 11 can be made in the form of three thin metal plates 34, the planes of which are oriented along the radius of the hollow metal cylinders 2 and rotated at an angle of (120 ± 10) ° relative to each other. One of the ends of each of the thin metal plate 34 abuts against the cylindrical surface 35 of the dielectric resonator 11, and the opposite end of this thin metal plate 34 is fixed relative to the inner surface 36 of the hollow metal cylinder 11.

The communication elements 32 with the coaxial resonator 22 can be made in the form of flat communication loops 37.

The outer surface of the second hollow metal cylinders 4 can be made in the form of flat radiators 38.

Diplexer works as follows.

Coaxial connectors 6 and 29 are connected to microwave transmission lines. In the presence of a multi-frequency electromagnetic wave in the line connected to connector 6, communication loops 12 and 13 with input 14 and 15 cylindrical dielectric resonators 11, respectively, of the first 16 and second 17 band-pass filters, excite electromagnetic oscillations at the resonant frequencies of the respective resonators 14 and 15. Resonators 14 and 15 transmit electromagnetic energy at appropriate frequencies through resonators 11, communication loops 12 and 13 to coaxial resonators 22.

The screws 25 of the tuning elements of the resonant frequencies of the cylindrical dielectric resonators 11 correct the changes in the resonant frequencies of the cylindrical dielectric resonators 11 resulting from tuning the connection between them. The connection between the cylindrical dielectric resonators is adjusted by changing the distance between them. Distance change is achieved

mutual movement of the hollow metal cylinders 2 due to the rotation of the second hollow metal cylinders 4.

The resonance frequency settings of the coaxial resonators 22 are carried out by conductive screws 27, each installed coaxially to the conductive rod 23 on the extreme end walls 21 of the last hollow metal cylinders 19.

Communication settings between the cylindrical dielectric resonators 11 installed in the penultimate hollow metal cylinders 2 and the coaxial resonators 22 are carried out by screws 29 installed in the holes 20 between the penultimate 18 and the last 19 hollow metal cylinders 2.

It was experimentally established that the loss in the passband of the bandpass filters 16 and 17 is reduced, and the isolation between the passband of these filters increases if the coupling loop 12 with the input cylindrical dielectric resonator 14 of the first 16 bandpass filter is made with a length equal to half the wavelength at the resonant frequency of the input cylindrical dielectric resonator 14 of the first 16 band-pass filter, and the communication loop 13 with the input cylindrical dielectric resonator 15 of the second 1 7 bandpass filter is made with a length equal to half the wavelength at the resonant frequency of the input cylindrical dielectric resonator 15 of the second 17 bandpass filter.

It has been experimentally established that the coupling loops 12 and 13 made in the form of conical spirals in some cases allow optimally achieving an increase in the coupling between the cylindrical dielectric resonators 11 in the last 19 hollow metal cylinders 2 and with minimal deterioration of the quality factor of cylindrical dielectric resonators 11.

The execution of axisymmetric holders 31 of each cylindrical dielectric resonator 11, in the form of three thin metal plates 34, the planes of which are oriented along the radius of the hollow metal cylinders and rotated at an angle of (120 ± 10) ° relative to each other, while one of the ends of each of the thin the metal plate 34 abuts against the cylindrical surface 35 of the dielectric resonator 11, and the opposite end of this thin metal plate 34 is fixed relative to the inner surface 36 of the hollow metal th cylinder 11, can dramatically reduce the number and level of spurious passband.

When performing the communication elements 32 with the coaxial resonator 22 in the form of flat communication loops 37 provides a smooth adjustment of the desired connection between the cylindrical dielectric resonator 11 and the supply line.

The implementation of the outer surface of the second hollow metal cylinders 4 in the form of flat radiators 38 provides a heat sink from the filter in microwave paths of a high power level.

The application of the proposed technical solution made it possible to create in the frequency range 4-5 GHz dielectric diplexers with nine-link bandpass filters with the following parameters: passband of the first and second filters ~ 3%, loss in the band is not worse than 1.3 dB, attenuation level in the band frequencies of the adjacent channel more than - 80 dB, applicable in paths with a power of up to 100 watts.

Claims (6)

1. A diplexer comprising a segment of a circular cylindrical waveguide with extreme end walls, an input coaxial connector mounted orthogonally relative to the cylindrical wall of a segment of the cylindrical waveguide, communication loops with input cylindrical dielectric resonators of the first and second band-pass filters, each formed by cylindrical dielectric resonators, coaxially located along the axis of a segment of a circular cylindrical waveguide on one and other sides of the input coac the sial connector with a central conductor and axially symmetric holders fixed in it, and the output cylindrical dielectric resonators of the first and second band-pass filters are electromagnetically connected each to output communication elements connected to the output coaxial connectors of the first and second frequency channels, and a metal wall with an orthogonal hole the cross section of a segment of a circular cylindrical waveguide, characterized in that it is provided with intermediate conductive walls with holes communications, second metal end walls, additional conductive rods, tuning elements of the resonant frequencies of cylindrical dielectric resonators, tuning elements of the resonant frequencies of coaxial resonators, communication settings between open dielectric and coaxial resonators, all tuning elements are made in the form of screws, a section of a circular cylindrical waveguide is made of hollow metal cylinders with external threads located at their ends, and second hollow thallic cylinders with internal threads located at their ends, all hollow metal cylinders are threaded and form an external cylindrical screen, the input coaxial connector is located orthogonally relative to the outer cylindrical surface of the hollow metal cylinder, the metal wall is installed in the cross section of the hollow metal cylinder passing through the axis of symmetry input coaxial connector, the hole in the metal wall is located at the inner cylindrical surface hollow metal cylinder at the installation site of the input coaxial connector, the central conductor of the input coaxial connector is located in the hole in the metal wall parallel to its plane, and the communication loops with the input cylindrical dielectric resonators of the first and second bandpass filters, respectively, are connected to the central conductor of the input coaxial connector and are located each parallel to the plane of the metal wall on its opposite sides, with the last and last cylinders at the ends of the outer cylindrical screen on each side of the input coaxial connector are arranged orthogonally, in the holes formed at the intersection of their cylindrical surfaces are intermediate conductive walls that coincide with the surface of the penultimate hollow metal cylinders, the end hollow metal cylinders of the screen are made with second metal end walls, in each of the penultimate hollow metal cylinders an additional end a wall, in each of the last hollow metal cylinders there is an additional rod forming a coaxial resonator and mounted on the second metal end wall of the extreme hollow metal cylinder, the resonance frequency tuning elements of the cylindrical dielectric resonators are installed in the penultimate hollow metal cylinders, the screws of which are located in the additional end walls in parallel end walls of cylindrical dielectric resonators, resonance clock tuning screws coaxial resonators, each mounted coaxially to the conducting rod on the extreme end walls of the extreme hollow metal cylinders, the communication adjustment screws between the open disk dielectric resonators and the coaxial resonators are located in the penultimate hollow metal cylinders and are located in the communication holes in the intermediate conductive walls of the penultimate and last hollow metal cylinders , output coaxial connectors, each mounted orthogonally relative to the cylindrical wall extreme hollow metallic cylinder. 2. The diplexer according to claim 1, characterized in that the communication loop with the input cylindrical dielectric resonator of the first band-pass filter is made with a length equal to half the wavelength at the resonant frequency of the input cylindrical dielectric resonator of the first band-pass filter, and the communication loop with the input a cylindrical dielectric resonator of the second bandpass filter is made with a length equal to half the wavelength at the resonant frequency of the input cylindrical dielectric resonator second second pass filter. 3. The diplexer according to claim 2, characterized in that the communication loop is made in the form of conical spirals. 4. The diplexer according to claim 3, characterized in that the axisymmetric holders of each cylindrical dielectric resonator are made in the form of three thin metal plates, the planes of which are oriented along the radius of the hollow metal cylinders and are rotated at an angle of 120 ± 10 ° relative to each other, while one of the ends of each of the thin metal plates abuts against the cylindrical surface of the dielectric resonator, and the opposite end of this thin metal plate is fixed relative to the inner surface hollow metal cylinder. 5. The diplexer according to claim 4, characterized in that the communication elements with the coaxial resonator are made in the form of flat communication loops. 6. The diplexer according to claim 5, characterized in that the outer surface of the second hollow metal cylinders is made in the form of flat radiators.