RU78373U1 - BAND FILTER FILTER - Google Patents

Abstract

The utility model is designed to create frequency-separation devices and allows to reduce losses in the pass-band of its frequency channels and to increase the isolation between the bands allowing channels. The filter contains a hollow cylindrical metal screen 1, at the opposite ends of which there are mounted connectors 2, which are made in the form of waveguide flanges, n open disk dielectric resonators 3 with holders installed in the screen 1, the flat surfaces of the resonators 3 are parallel to the longitudinal axis of the screen 1. Number n open disk dielectric 3 resonators determines the number of resonant links of the filter, forming its frequency response. The filter has n dielectric cylinders 4, n frequency adjustment screws 5 and (n-1) communication adjustment screws 6. For resonators, 3 axes are perpendicular to the longitudinal axis of screen 1, and adjacent resonators are mounted relative to each other so that their axes are located at an angle from zero to 45 °, the distance l between adjacent resonators is selected from the condition 2d≤l≤4d, where d is the diameter of the open disk dielectric resonator 3. The holder of each resonator 3 is made in the form of a screw 7 mounted on a thread in the side wall 8 of the screen 1. K screw end 7 inside the screen 1, one of the ends of the cylinder 4 is rigidly attached, the opposite end of which is rigidly connected to the flat surface of the resonator 3. The screw 5 is screwed into the wall 8 of the screen 1 coaxially to each resonator 3, and the length of the screw 5 is selected from the condition not less than the wall thickness 8 and not more half the diameter of the hollow screen 1. At half the distance l between each pair of resonators 3, a coupling screw 6 is screwed into the wall 8 of the screen 1, the axis of which is perpendicular to the longitudinal axis of the screen 1 and is located at an angle relative to the axes of the neighboring resonators 3, equal to the floors no angle between them. 8 ill.

Description

The utility model relates to microwave technology and is intended to create bandpass filters based on open disk dielectric resonators mainly in the centimeter wavelength ranges.

Known bandpass filters with planar arrangement of open disk dielectric resonators (see Dielectric resonators / under the editorship of Professor M.E. Ilchenko. - M .: Radio and communications, 1989, 328 p., P. 250, Fig. 10. 12), which contain a segment of a waveguide that acts as a screen beyond the filter in the operating frequency band, and open disk dielectric resonators with a lower mode of vibration, the number of which is equal to the number of filter links and each of which is mounted planarly in a segment of a cylindrical waveguide and is held in it using a dielectric sleeve. Each end of the screen ends with an attachment to the paths of the supply lines, for example, a metal end wall perpendicular to the longitudinal axis of the screen, on which, for communication with the supply lines, communication elements are made in the form of conductors connected to the central conductors of coaxial connectors mounted on the end walls.

However, such filters have large longitudinal dimensions, determined by the distance between the dielectric resonators, which in turn are associated with the slow attenuation of the external fields of the dielectric resonators that determine the electromagnetic coupling between them.

Closest to the claimed utility model is a band-pass filter containing n - sections, where n is the number of resonant links made in the form of hollow metal cylinders with threads located at the ends connected to each other, fixed with locknuts and forming an external cylindrical screen, and (n-2) open disk dielectric resonators, each of which is mounted in a hollow metal cylinder of the section with a holder,

the surfaces of disk dielectric resonators are oriented in the hollow metal cylinders of the sections parallel to the longitudinal axis of the hollow metal cylinders, the holder of each open disk dielectric resonator is made in the form of a dielectric stand attached to the inner surface of the hollow metal cylinder, and the end sections of the screen are made with metal end walls, in each of the end sections of the screen is installed communication element, for example loop, to one of the ends of the communication element attached a single central conductor of the coaxial connector (see patent for the invention RU No. 2295806, IPC H01P 1/20, publ. 20.03.2007).

The disadvantage of such filters is their complex design due to the presence of threaded connections, which complicates their mass production.

The technical task of the proposed utility model is to simplify (suitable for mass production) and reduce the dimensions of the design of band-pass filters on open disk dielectric resonators.

The solution to this problem is achieved by the fact that the known band-pass filter containing a hollow cylindrical metal screen, at the opposite ends of which there are connectors, n open disk dielectric resonators with holders, where n is an integer no less than one, installed in a hollow metal screen, and flat surfaces of open disk dielectric resonators are parallel to the longitudinal axis of the metal screen, equipped with n dielectric cylinders, n frequency tuning screws and (n-1) communication adjustment screws, the axes of open disk dielectric resonators are located perpendicular to the longitudinal axis of the hollow cylindrical metal screen, and adjacent disk dielectric resonators are mounted relative to each other so that their axes are at an angle from zero to 45 °, the distance l between adjacent open disk dielectric resonators is selected from the condition 2d≤l≤4d, where d is the diameter of the open

of a disk dielectric resonator, the holder of each open disk dielectric resonator is made in the form of a screw mounted on a thread in the side wall of a hollow cylindrical metal screen, one of the ends of the dielectric cylinder is rigidly attached to the end of the screw inside the hollow cylindrical metal screen, for example, with glue, the opposite end of the dielectric cylinder rigidly connected to the flat surface of an open disk dielectric resonator, for example, with glue, a tuning screw often you are screwed into the wall of the hollow cylindrical metal screen coaxially with each open disk dielectric resonator, and the length of the frequency adjustment screw is selected from the condition not less than the wall thickness and not more than half the diameter of the hollow cylindrical metal screen, and at half the distance l between each pair of open disk dielectric resonators in a screw for adjusting the coupling screw, the axis of which is perpendicular to the longitudinal axis of the hollow cylindrical metal of the screen and is located at an angle relative to the axes of adjacent open disk dielectric resonators, equal to half the angle between them, the connectors are made in the form of waveguide flanges.

The invention is illustrated by drawings, where Fig. 1 shows a longitudinal section of a band-pass filter on dielectric resonators, Fig. 2 shows a section A-A of a filter, Fig. 3 shows a section B-B, and Fig. 4 shows a section B-B , FIG. 5 shows a cross-section G-G, FIG. 6 shows a cross-section DD, and FIG. 7 shows a cross-section EE of the filter. On Fig presents the appearance of a seven-link (n = 7) bandpass filter on dielectric resonators for Ku wavelength range.

The band-pass filter contains a hollow cylindrical metal screen 1, at the opposite ends of which there are mounted connectors 2, which are made in the form of waveguide flanges, n open disk dielectric resonators 3 with holders, where n is an integer no less than one, installed in a hollow cylindrical metal

screen 1, and the flat surfaces of the open disk dielectric resonators 3 are parallel to the longitudinal axis of the hollow cylindrical metal screen 1. The number n of open disk dielectric 3 resonators determines the number of resonant links of the filter forming its frequency response. Above, the number n is limited by the allowable value of the attenuation of the useful signal in the passband of the filter. Typically, the number of resonant filter links on dielectric resonators does not exceed 15, i.e. lies in the range from 1 to 15.

The band-pass filter has n dielectric cylinders 4, n frequency adjustment screws 5 and (n-1) communication adjustment screws 6. For open disk dielectric resonators, 3 axes are located perpendicular to the longitudinal axis of the hollow cylindrical metal screen 1, and adjacent disk dielectric resonators are mounted one on the other relative to each other so that their axes are located at an angle from zero to 45 °, the distance l between adjacent open disk dielectric resonators is selected from the condition 2d≤l≤4d, where d is the diameter of the open dis dielectric resonator 3. The holder of each open disk dielectric resonator 3 is made in the form of a screw 7 mounted on a thread in the side wall 8 of the hollow cylindrical metal screen 1. To the end of the screw 7 inside the hollow cylindrical metal screen 1 is rigidly attached, for example, with glue, one of the ends of the dielectric cylinder 4, the opposite end of which is rigidly, for example, glued to the flat surface of the open disk dielectric resonator 3. Frequency adjustment screw 5 is screwed into the wall 8 of the hollow cylindrical metal screen 1 coaxially with each open disk dielectric resonator 3, and the length of the frequency adjustment screw 5 is selected from the condition not less than the wall thickness 8 and not more than half the diameter of the hollow cylindrical metal screen 1. At half the distance l between each pair of open disk dielectric resonators 3 into the wall 8 of the hollow cylindrical metal screen 1 screw screw settings 6, the axis of which is perpendicular

the longitudinal axis of the hollow cylindrical metal screen 1 and is located at an angle relative to the axes of adjacent open disk dielectric resonators 3, equal to half the angle between them.

The bandpass filter operates as follows.

After connecting the connectors 2 to the circuit with a propagating microwave wave, the extreme (closest to the waveguide flanges 2) open disk dielectric resonators 3 provide the input and output of energy in the filter-transmission line system. A hollow cylindrical metal screen 1, transcendent in the working frequency band of the filter, eliminates out-of-band energy transfer between the input and output and provides electromagnetic coupling between open disk dielectric resonators 3.

The holders of each open disk dielectric resonator 3 in the form of a screw 7 mounted on a thread in the side wall 8 of the hollow cylindrical metal screen 1, rigidly attached to it one of the ends of the dielectric cylinder 4, and the opposite end of the dielectric cylinder 4 to the flat surface of the open disk dielectric resonator 3 allows the necessary primary adjustment of the required resonant frequency of the resonant link formed by an open disk dielectric resonator 3. The presence of a frequency adjustment screw 5 screwed into the wall 8 of the hollow cylindrical metal screen 1 coaxially with each open disk dielectric resonator 3, with its length selected from the condition not less than the wall thickness 8 and not more than half the diameter of the hollow cylindrical metal screen 1, allows you to adjust the frequency of the resonance link when tuning the filter to the specified parameters of its amplitude-frequency characteristics.

The distance l between the open dielectric resonators 3 is chosen as the smallest possible, i.e. not less than 2d. It was experimentally established that the maximum permissible distance l is 4d when the axes of adjacent open dielectric resonators 3 are located at an angle from

zero to 45 °. An additional adjustment of the necessary mutual coupling between adjacent open dielectric resonators 3 is achieved by using the communication adjustment screws 6. It has been experimentally established that the maximum effect of such adjustment is achieved if the communication adjustment screw 6, whose axis is perpendicular to the longitudinal axis of the hollow cylindrical metal screen 1 and is located at an angle relative to the axes adjacent open disk dielectric resonators 3, equal to half the angle between them, are screwed into the wall 8 of the hollow cylindrical metal screen 1 at half the distance l between each pair of open disk dielectric resonators 3.

It was experimentally established that the holders of each open disk dielectric resonator 3 in the form of a screw 7 mounted on a thread in the side wall 8 of the hollow cylindrical metal screen 1, rigidly attached to it one of the ends of the dielectric cylinder 4, and the opposite end of the dielectric cylinder 4 to a flat surface open disk dielectric resonator 3, carried out using glue on an epoxy basis, allows you to use the proposed band-pass filter p on dielectric resonators 3 in the paths of a high (up to 100 W) power level.

Using the utility model, it was possible to create multi-link bandpass filters with open disk dielectric resonators in the frequency range 12-18 GHz (passband - up to 3%, loss in the band no worse than 2 dB), designed for operation in paths with a power level of up to 100 W .

Claims (1)

A band-pass filter containing a hollow cylindrical metal screen, at the opposite ends of which there are connectors, n open disk dielectric resonators with holders, where n is an integer no less than one, installed in a hollow metal screen, the flat surfaces of the open disk dielectric resonators are parallel to the longitudinal the axis of the metal screen, characterized in that the filter is equipped with n dielectric cylinders, n frequency tuning screws and (n-1) tuning screws In connection with open disk dielectric resonators, the axes are perpendicular to the longitudinal axis of the hollow cylindrical metal screen, and adjacent disk dielectric resonators are mounted relative to each other so that their axes are at an angle from 0 to 45 °, the distance l between adjacent open disk dielectric resonators is selected from conditions 2d≤l≤4d, where d is the diameter of the open disk dielectric resonator, the holder of each open disk dielectric resonator is made in e of the screw mounted on the thread in the side wall of the hollow cylindrical metal screen, to the end of the screw inside the hollow cylindrical metal screen is rigidly, for example, glued, one of the ends of the dielectric cylinder is attached, the opposite end of the dielectric cylinder is rigidly, for example, glued, connected to the flat surface of the open of a disk dielectric resonator, a frequency tuning screw is screwed into the wall of a hollow cylindrical metal screen coaxially with each open disk dielectric p to the isolator, the length of the frequency adjustment screw being selected from the condition of not less than the wall thickness and not more than half the diameter of the hollow cylindrical metal screen, and at half the distance l between each pair of open disk dielectric resonators, a communication adjustment screw is screwed into the wall of the hollow cylindrical metal screen, the axis of which is perpendicular the longitudinal axis of the hollow cylindrical metal screen and is located at an angle relative to the axes of adjacent open disk dielectric resonators, equal th half angle therebetween attacher are in the form of waveguide flange.