RU166711U1 - PHASE ANTENNA ARRANGEMENT ELEMENT - Google Patents

Abstract

An element of a phased antenna array containing input and output dielectric emitters with round cylindrical recesses in the center of the ends, a waveguide ferrite phase shifter, consisting of a cylindrical wave ferrite rod of square cross section, placed together with its longitudinal magnetization winding inside an external magnetic circuit, made in the form of four П- shaped ferrite staples, each of which consists of a shelf and two shoes adjacent flat soles to one of the four x faces of the ferrite rod, the ferrite phase shifter waveguide in the form of a conductive coating on the side surface of the ferrite rod, the input and output waveguides, consisting of emitter waveguides, matching waveguides and transformers located between the ends of the ferrite rod and the shanks of the dielectric emitters, and a case in the form of a cylindrical sleeve, characterized the fact that the depth of the circular cylindrical recess in the center of the emitter end exceeds the height of the circular cylindrical protrusion 0.2-0.3 mm, forming an air gap.

Description

This utility model relates to the field of microwave and UHF radio engineering, in particular, to designs of phased antenna emitters for phased array antennas (PAR), and can be used in radar systems with wide-angle electric scanning of the antenna beam.

At present, spatial excitation PAR elements are finding more and more application, in which the electromagnetic waves from the primary irradiator are received by one (for example, input), and their radiation into space - by other (for example, output) emitters.

Elements of the headlamps performing electric scanning of the beam can be made, in particular, in the form of input and output waveguide-dielectric emitters connected in series and a waveguide ferrite phase shifter located between them with a longitudinal magnetization field transmitting electromagnetic waves polarized in a circle.

An urgent task is to develop waveguide ferrite phase shifters and AFR elements of a through type based on them, having small transverse dimensions for antenna systems with wide-angle electric beam scanning, operating on electromagnetic waves with circular polarization of the field. The creation of such PAR elements for the millimeter wavelength range is especially relevant, where the development of PAR elements with small transverse dimensions, high speed and low power consumption encounters certain technical difficulties.

Known transceiver element of a phased antenna array (see patent RU 2184410, IPC H01Q 21/00, H01P 1/19, published June 27, 2002). The known PAR element contains dielectric emitters and a phase shifter, consisting of a magnetizing winding located inside the magnetic circuit, and a cylindrical ferrite rod installed inside the magnetizing winding. Between the ends of the cylindrical ferrite rod and the ends of the dielectric emitters installed matching dielectric washers. In this case, a cylindrical ferrite rod, matching washers and dielectric emitters have the same diameter and are enclosed in a common segment of a circular waveguide. The magnetic circuit of this PAR element is made in the form of two U-shaped staples, each of which contains a longitudinal plate and two shoes, resting on the metallized side surface of the ferrite core. The supporting surface of the shoes is made in the shape of the side surface of the rod, and the inner surfaces of the shoes are ground with a high accuracy class and are tightly pressed to the surface of the metallized ferrite core.

The disadvantages of the known PAR element are: a high level of introduced microwave losses, long lengths, the difficulty of manufacturing individual parts and the assembly of the PAR element, low strength and resistance of the PAR element to shock and vibration.

A known PAR element (see patent RU 2325741, IPC H01Q 21/00, Н01Р 1/19, published May 27, 2008) containing dielectric emitters and a phase shifter, consisting of a magnetizing winding located inside the magnetic circuit, and a cylindrical ferrite rod installed inside the magnetizing windings. The cylindrical ferrite rod and dielectric emitters are enclosed in a common segment of a metallized circular waveguide and are made of materials with a high dielectric constant of equal or close value to each other. Dielectric emitters contain a cylindrical part and with one ends are rigidly connected to the ends of the cylindrical ferrite rod, and elongations in the form of truncated cones are made at their other ends, the diameter of the base of the truncated cones being less than the diameter of the cylindrical part of the dielectric emitter. In this case, the ends of the general segment of a metallized circular waveguide are separated by a distance of (0.05-0.1) λ ₀ from the base of the truncated cones whose height is (0.8-1.2) λ ₀ , where λ ₀ is the central wavelength 10 -percent range, the diameter of the base of the truncated cones is (0.8-0.9), and the diameter of their vertices is (0.5-0.6) of the diameter of the cylindrical part of the dielectric element.

In the known PAR element, a reduction in the complexity and cost of production of the PAR antenna element is achieved by simplifying its design. However, the PAR element has resonant peaks of microwave energy loss at higher types of waves. In addition, due to the high dielectric constant of the material of the emitters, which is the same or close to the dielectric constant of the material of the ferrite core, an increase in microwave losses in the PAR is inevitable due to the mismatch of its openings with free space in the beam scanning sector.

A known element of the PAR, coinciding with the claimed solution for the largest number of essential features and adopted for the prototype (see patent RU 2461931, IPC H01Q 21/00, Н01Р 1/16, published on September 20, 2012). The pass-through element of the PAR-prototype contains input and output dielectric emitters, a waveguide ferrite phase shifter, consisting of a cylindrical waveguide ferrite rod (FS) in the form of a regular N-faced prism (N≥4), placed together with its longitudinal magnetization winding inside an external magnetic circuit made in the form of N U-shaped ferrite staples. Each bracket consists of a shelf and two shoes adjacent flat soles to one of the N faces of the ferrite core. The element also includes a ferrite phase shifter waveguide formed by a thin film of a conductive coating of the side surface of the ferrite rod, a receiving and aperture waveguides consisting of emitter waveguides, matching and connecting waveguides, matching transformers in the form of dielectric inserts located between the ends of the ferrite rod and the shanks of the dielectric radiators, and case in the form of a cylindrical sleeve. Through the slots in the wall of the housing the wires of the magnetizing winding are brought out. The pass-through element of the PAR also contains washers made of dielectric placed on the FS between the ends of the longitudinal magnetization winding and the shoes of ferrite staples and adjoining the outer cylindrical surface to the inner cylindrical surface of the housing. The dielectric insert is made in the form of washers from a material with a dielectric constant ε _in = 9.5-10.5.

The known PAR element has reduced lateral dimensions, simplified construction, strength and resistance to shock and vibration. A disadvantage of the known element is the lack of structural elements that ensure alignment of the matching washer and the cylindrical part of the emitter. In the known construction, the dielectric washer will inevitably, when assembling the phase shifter, be displaced from the axis close to the wall of the hole in the waveguide. On the opposite side, an air gap is equally inevitable.

This effect will lead to the depolarization of the circularly polarized wave of the microwave signal and, due to this, to increased cross-polarization losses in the phase shifter.

The objective of this utility model is to develop such a PAR element that, while maintaining small losses of the microwave signal, would have small cross-polarization losses.

The problem is solved in that the PAR element includes an input and output dielectric emitters with round cylindrical recesses in the center of the ends, a waveguide ferrite phase shifter, consisting of a cylindrical waveguide ferrite rod of square cross section, placed together with its longitudinal magnetization winding inside an external magnetic circuit, made in in the form of four U-shaped ferrite staples. Each bracket consists of a shelf and two shoes adjacent flat soles to one of the four faces of the ferrite core. The element also includes a ferrite phase shifter waveguide in the form of a conductive coating on the side surface of the ferrite rod, input and output waveguides, consisting of emitter waveguides, matching waveguides and short-circuiting devices, as well as matching transformers placed between the ends of the ferrite rod and the shafts of dielectric radiators, and the housing in in the form of a cylindrical sleeve. New in the PAR element is the design of the matching transformer in the form of a dielectric disk with a round cylindrical protrusion in the center, which is inserted into a circular cylindrical recess at the end of the dielectric emitter. The depth of the circular cylindrical recess in the center of the end face of the emitter exceeds the height of the circular cylindrical protrusion of the matching transformer by (0.2-0.3) mm. The air gap formed at the end of the cylindrical protrusion, on the one hand, guarantees a gapless connection of the matching disk with the end of the emitter, on the other hand, it plays the role of an additional matching stage and extends the matching frequency band. Fixing the transformer strictly on the axis of the emitter ensures the preservation of the circular polarization of the microwave signal.

The present utility model is illustrated in the drawing, where

in FIG. 1 shows a side view of the present PAR element with a partial longitudinal section;

in FIG. 2 shows a cross-section along aa of the PAR element.

In FIG. 1-fig. 2 marked: 1 - input dielectric emitter; 2 - output dielectric emitter; 3 - input waveguide of the emitter; 4 - output waveguide of the emitter; 5, 6 - matching waveguides; short circuits 7, 8 matching waveguides 5, 6; square waveguide ferrite rod 9, ferrite phase shifter waveguide 10 in the form of a conductive coating of the side surface of the ferrite rod 9, its longitudinal magnetization winding 11, located inside the external magnetic circuit, made in the form of four U-shaped ferrite brackets 12, each of which consists of a shelf 13 and two shoes 14 and 15 adjacent flat soles to one of the four faces of the ferrite rod 9; matching transformers 16, housing 17 in the form of a cylindrical sleeve. Matching transformers 16 are made in the form of dielectric disks 19, having circular cylindrical protrusions 20 located strictly on their axis and inserted into circular cylindrical recesses 21 of the dielectric emitters 1 and 2, and abutting against the ends of the waveguide ferrite rod 9. With their other sides, the depth of the round a cylindrical recess 21 in the center of the end face of each emitter 1, 2 exceeds the height of the round cylindrical protrusion of the matching transformer 16 by 0.2-0.3 mm, forming an air gap. The diameter of the circular cylindrical recess 21 exceeds the diameter of the circular cylindrical protrusion 20 of the matching transformer 16 by only 0.01-0.02 mm.

This element of the PAR is as follows.

In the transmission mode, an electromagnetic wave polarized in a circle emitted by an irradiator of a phased array (not shown) composed of PAR elements is received by the input dielectric emitter 1 of each PAR element and excites in its cylindrical part a wave of type HE _{11 of the} dielectric waveguide, and then a wave of type H ₁₁ in an input waveguide 3 of the input transducer 1. Then, the electromagnetic wave passes through the input matching junction formed waveguide portion 3 with a complex dielectric filling (in ce eniyah recess 21 and protrusion 20) and the matching waveguide 5 filled with material of the transformer 16, and excites a waveguide ferrite phase shifter 10, attached through a short circuit 7, a lower wave type H ₁ square waveguide filled ferrite medium. From the output of the ferrite phase shifter inserted in the short circuit 8, the electromagnetic wave enters the matching waveguide 6, waveguide 4 of the output dielectric emitter 2 and is emitted into the free space by the output dielectric emitter 2. The phase of the radiated circular element of the PAR element of the electromagnetic wave depends on the wavelength, the diameter of the cross section, the dimensions of the input and output emitters 1, 2 and the input and output waveguides 4, 5, as well as the parameters of the materials of the dielectric emitters 1, 2, tr the descriptor 16 and the ferrite rod (FS) 9. An additional change in the phase of the electromagnetic wave in the interval Δφ = 0 ÷ 2π is carried out by means of the Faraday-type waveguide ferrite phase shifter by changing the parameters of the ferrite medium FS 9 during its longitudinal magnetization. The magnetization field is created in FS 9 by a winding 11 of its longitudinal magnetization connected to the beam control system of the PAR (not shown).

In the reception mode from free space, a plane polarized electromagnetic wave with an opposite direction of rotation is incident on the output dielectric emitter 2 of the PAR element and is received by it. Then the electromagnetic wave sequentially passes through the segments of the waveguides (4, 6, 10, 5, 3) of the waveguide channel of the PAR element in the opposite direction, receives the same as in the transmission mode, an additional phase change Δφ in the phase shifter and is emitted by the input dielectric emitter 1 in headlight illuminator.

This element of the PAR is distinguished by the simplicity of manufacturing individual parts and blocks and the assembly of the device as a whole. In its manufacture can be used normalized, commercially available materials, adhesives and processes. The input waveguide formed by the waveguide 3, the matching waveguide 5 and the short circuit 7, as well as the output waveguide formed by the waveguide 4, the matching waveguide 6 and short circuit 8, it is advisable to produce in the form of a single part in the form of a glass, in the bottom of which a square window is cut down. Production can be carried out on high-performance equipment. The housing 17 of the PAR element is expediently made by cutting from a thin-walled pipe previously made by pulling. Dielectric emitters 1, 2 can be made, for example, of a composite material (microwave ferrites and dielectrics / Prospect.-S-Pb .: OJSC Magneton Plant, 2016. - 20 s.) With a relative permittivity ε _u = 3, 5-4.5 and are made by molding, pressing or machining. Similarly, composite transformers with a relative dielectric constant ε _and = 9-11 (microwave ferrites and dielectrics / Prospect.-S-Pb .: OJSC Magneton Plant, 2016. - 20 p.) Can be made matching transformers 16. Winding control 11, it is advisable to do frameless with impregnation with glue (for example, BF-6). For the manufacture of FS 9 and ferrite staples 12, normalized ferrite materials can be used (microwave ferrites and dielectrics / Prospect.-S-Pb .: OJSC Magneton Plant, 2016. - 20 s), for example, for the manufacture of a PAR element of the millimeter range ferrite marks 1SCH12. The simplicity of the shape and seating surfaces of these parts makes it possible to use the widely used flat diamond grinding process in their manufacture. Transformers 16, it is advisable to connect to the emitters 1 and 2 without glue, by inserting the protrusion of the transformer into the hole in the emitter to the stop. It is advisable to assemble the ferrite phase shifter, consisting of the rod 9, the coil 11 and the staples 12, separately in the form of a single ferrite block, the details of which are connected by glue, for example, BF-6. The assembly of this PAR element is advisable to carry out by gluing the individual parts using normalized adhesives. In particular, for gluing the input or output waveguide (3, 5, 7 or 4, 6, 8) with a dielectric emitter 1 or 2 with a transformer 16 inserted into it, as well as for connecting these waveguides to the housing 17, it can be used epoxy adhesive brand VK-9. The connection of short-circuiting devices 7, 8 and metallized FS 9, 10 should be carried out with an electroconductive adhesive of the EK-S brand, which is used in installation operations in the manufacture of electronic products and can withstand thermal cycling in the temperature range from minus 60 to + 85 ° C. To seal the device, the openings for the conclusions of the magnetization winding 11 can be filled with sealant.

The effectiveness of this technical solution was tested experimentally on mock-ups of elements of a phased antenna array of the millimeter wavelength range in the frequency band of a rectangular waveguide with a cross section of 7.2 × 3.4 mm ² . The layout of the PAR element weighs no more than 2 grams and has a transverse dimension of no more than 0.6λ. When measuring the cross-polarization losses of the layout, it was compared with its analogue. A decrease in cross-polarization losses in the layout of the PAR element was recorded by 20% while maintaining small losses of the microwave signal.

Claims (1)

An element of a phased antenna array containing input and output dielectric emitters with round cylindrical recesses in the center of the ends, a waveguide ferrite phase shifter, consisting of a cylindrical wave ferrite rod of square cross section, placed together with its longitudinal magnetization winding inside an external magnetic circuit, made in the form of four П- shaped ferrite staples, each of which consists of a shelf and two shoes adjacent flat soles to one of the four x faces of the ferrite rod, the ferrite phase shifter waveguide in the form of a conductive coating on the side surface of the ferrite rod, the input and output waveguides, consisting of emitter waveguides, matching waveguides and transformers located between the ends of the ferrite rod and the shanks of the dielectric emitters, and a case in the form of a cylindrical sleeve, characterized the fact that the depth of the circular cylindrical recess in the center of the emitter end exceeds the height of the circular cylindrical protrusion 0.2-0.3 mm, forming an air gap.

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