RU2598182C1 - Rotary connection - Google Patents

Abstract

FIELD: radar.

SUBSTANCE: invention relates to radar engineering, particularly, to antenna-feeder system devices, used for transmitting microwave energy between the fixed part of the radar station, for example, stationary (fixed) transmitters, receivers, and rotary antenna system. Connection includes coaxial lines in the form of movable relative to each other cylinders, excitable at the points, evenly distributed along the perimeter at the ends of cylinders, adjustable elements and two-stage dividers, representing symmetrical tees connections, the output arms of which are made in the form of transformers. At that the transformers being the output arms of the first stage tees, are made of several series-connected non-resonance transmission line sections with different wave resistance, decreasing from the first stage tee inlet to the second stage tees inlets, and transformers being the output arms of the second stage tees, represent non-resonance transmission line sections, with variable impedance, increasing from the tees inputs to the places of connection to connected coaxial lines.

EFFECT: technical result consists in increase of operating frequency tuning capabilities in a wide range and reduction of dimensions while maintaining good matching and low losses of microwave signal.

1 cl, 1 dwg

Description

The present invention relates to the field of radar technology, in particular, to devices of the antenna-feeder system used to transmit microwave energy between the fixed part of the radar station, for example, stationary (fixed) transmitters, receivers, and a rotating antenna system.

When developing a radar station (radar), the problem arises of creating a high-frequency rotating connection for transmitting microwave signals from the fixed part, in which the transmitters and receivers are located, to the rotating part with the antenna system installed on it. A rotating connection must ensure the transmission of both powerful, coming from the output of the transmitting device to the antenna system, and weak, coming from the antenna system to the input of the receiving devices, microwave signals. In this case, the rotating connection must have good coordination, low loss of the microwave signal. In addition, often a rotating connection must simultaneously transmit various microwave signals over several channels.

So, a remote analogue of the claimed invention is a rotating connection (patent RU No. 1840482 class. IPC: H01P 1/06, publ. 03/27/2007), containing rotating and fixed dielectric rings installed with a gap, on the corresponding surfaces of which are grounded conductive plates and ring strip lines equipped with radial inputs, excitation systems with equal amplitude and common mode division and transformation of wave impedances, and the ring strip lines are located on two concentric tracks, would be formed conjugated circular arcs of equal radii, the centers of which are offset with respect to common rotation axis and are in the form of incomplete rings intertwined with bends in places of transition from one concentric track to another, wherein the inlets and radial fractures are grouped and arranged symmetrically and uniformly.

This non-contact rotating joint has small overall dimensions.

However, this device has the following disadvantages:

- a low level of operating power, due to the fact that the conductors of the disk are made on foil material. Limitations on the level of working power are caused by the small transverse dimensions of the metallized layer, which is heated at high power values, which causes, for example, peeling of the metallized layer from the dielectric base.

- a small range of operating frequencies caused by the “tandem” connection of several sections of directional couplers with distributed coupling, each of which is a resonant segment of a high-frequency line, since the preferred electrical length of each section of a directional coupler is equal to a quarter of the wavelength of the operating range;

- complexity in the development and use in the high-frequency (decimeter) range. This is due to the fact that with an increase in the operating frequency range, the geometric dimensions of high-frequency lines decrease, since each of the high-frequency lines, forming a section of directional couplers, has a length equal to a quarter of the wavelength of the operating range. This entails, as a rule, a decrease in all geometric dimensions, including the width of high-frequency lines. Reducing all geometric dimensions leads to an increase in the influence of inaccuracies and errors that appeared during the production process, and, consequently, to toughening the requirements (reducing tolerances) in the manufacture of components and parts included in the device. In addition, reducing the width of the high-frequency lines leads to an even greater reduction in the level of operating power. An increase in the width of high-frequency lines leads to an increase in the relative length of zigzag fractures, which negatively affects the width of the operating frequency range and the stability of parameters (matching, loss, phase shift stability) during rotation, i.e. difficulties in creating a rotating connection of this type for operation in the high frequency range.

A closer analogue, selected as a prototype in connection with the similarity of the technical task being performed, is a rotating connection (R No. 2260229, IPC: H01P 1/06, published September 10, 2005) containing concentrically arranged segments of coaxial lines with quarter-wave short-circuited insulators made based on a plane-parallel radial line, and matching transitions at the ends, movably articulated through a system of quarter-wave throttle clearances, are made in the form of two parallel branches of a strip line containing m foot transformers of resistance.

This device has a higher level of working power, due to the fact that the device does not use foil materials, rotating (rotor) and fixed (stator) segments of coaxial lines are made of metal. The cross-sectional area of the conductors is significantly larger than the cross-sectional area of the disk conductors made on the foil material.

The design allows you to use the device in a higher frequency region.

However, this device also has disadvantages:

- limited number of channels. The limitation of the number of channels is due to the geometric dimensions of the segments of the coaxial line of the external channel. With an increase in the diameter of the segments of the coaxial line, it becomes necessary to increase (from 2 to 4 or more) the connection points of the outputs of the rotating joint with the segments of the coaxial lines, since when using only 2 connection points the segments of the coaxial lines are excited non-uniformly, which leads to increased microwave signal loss and poor matching. An increase from 2 to 4 connection points of the outputs of a rotating connection, as a rule, is achieved by using a divider (adder) by 4, which is a cascade connection of dividers (adders) by 2, which can also carry out the functions of resistance transformers. The divider of each cascade consists of a symmetrical tee having an input and 2 outputs connected to the input by segments of a transmission line having a length equal to a quarter of the wavelength, and wave impedance other than the wave impedance of the inputs and outputs. Thus, the divider of each cascade is a divider similar to the divider described in: Design of lens, scanning, wide-range antennas and feeder devices. Zhuk M.S. and Molochkov Yu.B. Moscow, Energia, 1973, p. 428. The presence of resonant segments (transmission line segments having a length equal to a quarter of the wavelength) as part of the dividers reduces the range of operating frequencies. Cascading dividers further limits the range of operating frequencies. Thus, an increase in the number of channels leads either to an increase in the loss of the microwave signal and to a deterioration of matching, or to a narrowing of the working frequency band;

- a small range of operating frequencies of each individual channel, due to the presence of two parallel branches of the strip line containing resonant multi-stage resistance transformers.

The objective and technical result of the invention is to increase the power and throughput of a rotating joint by increasing the number of channels by expanding the diameters of concentrically arranged segments of coaxial lines while increasing the range of working frequencies of the channels, while maintaining good matching and low losses of the microwave signal.

The specified technical result is achieved in that the rotating connection contains concentrically arranged segments of coaxial lines, excited at points on the ends of the segments of coaxial lines, matching transitions at the ends, movably articulated by a system of quarter-wave chokes. According to the invention, the segments of the coaxial lines of the rotating joint are made excited at four points evenly spaced along the perimeter at the ends of the segments of the coaxial lines, and the matching transitions are made in the form of two cascade dividers, which are connections of symmetrical tees, the output arms of which are made in the form of transformers, and transformers, which are the output shoulders of the tees of the first cascade, are made up of several non-resonant segments connected in series transmission lines having different wave impedances decreasing from the input of the tee of the first stage to the inputs of the tees of the second stage, and transformers that are the output arms of the tees of the second stage are non-resonant line segments having a variable wave resistance increasing from the inputs of the tees to the points of connection to pieces of coaxial lines.

Distinctive features of the excitation of coaxial lines, matching transitions and design of transformers allow to achieve the claimed technical result, namely:

- ensuring the excitation of segments of coaxial lines at 4 (in contrast to the prototype at 2) points and uniform distribution around the perimeter at the ends allows to increase the number of transmission channels of microwave signals and the total power of energy transmitted through a rotating connection;

- the implementation of matching transitions in the form of two cascade dividers, which are compounds of symmetrical tees, the output arms of which are made in the form of transformers, the transformers being the output arms of the tees of the first stage, made up of several series-connected non-resonant segments of the transmission line having different wave resistances, decreasing from the input of the tee of the first cascade to the inputs of the tees of the second cascade, and the transformers, which are the output arms tees of the second cascade are non-resonant line segments having a variable wave impedance increasing from the inputs of the tees to the points of connection to the segments of coaxial lines, which allows to improve the matching of junctions and thereby reduce the loss of microwave signals, increase the throughput of a rotating joint.

The invention will be more clear from the above description and the accompanying drawing, which shows the following:

In FIG. 1 shows a divider diagram of a proposed rotating joint.

In the drawing and in the text, the following notation:

1 - concentrically arranged segments of coaxial lines;

2 - outputs of the tee of the 1st cascade, which are simultaneously the inputs of the tees of the 2nd;

3 - outputs of tees of the 2nd stage;

4 - input of the tee of the 1st cascade;

5, 6, 7 - line segments between the outputs of the tees of the 1st and the inputs of the tees of the 2nd cascade;

8 - line segments between the inputs and outputs of the tees of the 2nd stage;

9 - adjusted items.

A rotating joint contains concentrically arranged segments of coaxial lines 1 excited in four pairs of points uniformly spaced along the perimeter at the ends of segments of coaxial lines 1. Transitions at the ends that are movably articulated by means of a system of quarter-wave throttle clearances are made in the form of two cascade dividers. Two-stage dividers are made in the form of a connection of symmetrical tees, the output shoulders of which are made in the form of transformers. The outputs of the 2 tees of the first stage are the inputs of the tees of the second stage, and the outputs of the tees of the second stage 3 are connected to the ends of the segments of the coaxial line 1. Moreover, the transformers of the first stage are made up of several series-connected non-resonant segments of the transmission line 5, 6, 7 having different wave resistances decreasing from the inputs 4 to the outputs of the tees 2 of the first stage, which are simultaneously the inputs of the tees of the second stage. The transformers connecting the outputs of the tees of the second stage to the segments of the coaxial lines 1 are made in the form of short non-resonant segments of the line 8 having a variable wave impedance increasing from the inputs of the 2 tees to the outputs of the 3 tees of the 2nd cascade (i.e., to the points where the dividers are connected to the ends of the segments of coaxial lines 1). The tuned elements 9 serve to obtain the necessary parameter values (matching, loss) in a wide frequency range and make it possible to compensate for the influence of technological variation obtained in the manufacture of parts and assemblies in the production process.

A rotating connection works as follows.

The microwave signal supplied to the input 4 of the tees of the first stage is divided and along the segments 5, 6, 7 of the high-frequency transmission line forming the transformers, it comes to the outputs 2 of the tees of the first cascade, which are simultaneously inputs of the tees of the second stage, and through short non-resonant segments 8 enters the outputs of 3 tees of the second cascade connected to segments of coaxial lines 1 at points evenly spaced along the perimeter of segments of coaxial lines 1. Adjusted elements 9 serve to obtain the necessary parameter values ( coordination, losses) in a wide range of frequencies and make it possible to compensate for the influence of technological spread resulting from the manufacture of parts and assemblies in the production process.

Since the transformers of the first stage are composed of several non-resonant segments 5, 6, 7 of the transmission line having different wave impedances, decreasing from the inputs 4 to the outputs 2 of the tees of the first stage, which are simultaneously the inputs of the tees of the second, and the connections of the outputs of the 3 tees of the second stage with coaxial segments lines 1 are made in the form of transformers based on short non-resonant sections of transmission line 8 having variable wave impedance increasing from the outputs of 2 tees to the points of connection If the ends of the coaxial line segments are 1, then the operating frequency range is determined not by the length of each of the segments 5, 6, 7, 8 and not by the sum of the lengths of the segments 5, 6, 7. Therefore, a decrease in the operating frequency range caused by the presence of several resonant segments (the presence of resonant segments in each of the dividers and the cascade connection of dividers) does not occur. This allows you to increase the number of channels by increasing the diameters of concentrically spaced segments of coaxial lines and to increase the range of operating frequencies with good matching and small losses of the microwave signal. In addition, the absence of resonant segments in the dividers makes it possible to reduce the dimensions of the dividers and, as a result, the entire rotating joint.

The refusal to use the design of quarter-wave short-circuited insulators, which are used to fasten the central conductors of coaxial lines and isolate them at a high frequency from the external conductors of coaxial lines, by changing the method of fastening the central conductors of coaxial lines allows you to further expand the operating frequency band of a separate channel of a rotating joint.

The use of tuned elements allows you to obtain the necessary parameter values (matching, loss) in a wide frequency range and allows you to compensate for the influence of technological variation obtained in the manufacture of parts and assemblies in the production process, which reduces the accuracy requirements for manufacturing parts and assemblies that make up a rotating joint , and thereby improve the manufacturability of the device.

At the filing date, a mock of a rotating joint was made, the divider of which is made using symmetrical strip lines.

The wave impedances of segments 5, 6, 7, 8 of the high-frequency transmission line included in the divider of the first stage are 100 Ohm, 47 Ohm, and 40 Ohm, respectively. The length of segment 5 is from 0.04λ to 0.07λ, the length of segment 6 is from 0.15λ to 0.23λ, and the length of segment 8 is from 0.03λ to 0.05λ. Thus, none of the segments has a length multiple of the wavelength, i.e. none of the segments is resonant. The sum of the lengths of segments 5, 6, 7 is from 0.22λ to 0.35λ, therefore, the length of the entire high-frequency transmission line containing segments 5, 6, 7 is not resonant.

The wave resistance of the segments of the transmission line 8, which are part of the dividers of the second cascade, varies from 40 Ohms at the beginning at the point of connection of the segments 8 to the input of 2 tees to 53 Ohms at the points of connection of the ends of the segments of coaxial lines 1. The length of the segments 8 is from 0.07λ to 0.11λ and is also not resonant.

Since neither the lengths of the segments of the transmission line included in the dividers, nor their sum are resonant, therefore, the bandwidth of the operating frequencies of the dividers does not have limitations associated with the lengths of the segments 5, 6, 7, 8 included in the dividers. As a result of experimental work, it was found that the model of a rotating joint can have a diameter of concentrically arranged segments of coaxial lines of more than a quarter of the wavelength. At the same time, each individual channel operates in the required operating frequency band and can be reconfigured (using the same SWR and microwave signal losses) in the operating frequency range from 1 GHz to 1.6 GHz with a SWR of no more than 1.5 and losses Microwave signal no more than 0.5dB.

The use of this invention will significantly increase the number of channels by increasing the diameters of concentrically arranged segments of coaxial lines while maintaining a large range of operating frequencies, good matching and small losses of the microwave signal, while increasing manufacturability by reducing the accuracy requirements for the manufacture of parts and assemblies included in composition of a rotating joint.

Claims (1)

A rotating joint containing concentrically arranged segments of coaxial lines excited at points on the ends of segments of coaxial lines, matching transitions at the ends, movably articulated by a system of quarter-wave throttle clearances, characterized in that the segments of coaxial lines are made excited at four points uniformly spaced around the perimeter the ends of the segments of coaxial lines, and matching transitions are made in the form of two cascade dividers, which are compounds of symmetry of tees, the output arms of which are made in the form of transformers, the transformers being the output arms of the tees of the first stage, made up of several series-connected non-resonant segments of the transmission line having different wave impedances decreasing from the input of the tee of the first stage to the inputs of the tees of the second stage, and transformers, which are the output arms of the tees of the second stage, are non-resonant line segments having an alternating wave resistance, increasing from the inputs of the tees to the places of joining to the segments of coaxial lines.

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