RU62741U1 - ANTENNA ELEMENT OF THROUGH PHASED ANTENNA ARRAY - Google Patents

Abstract

The invention relates to antenna technology, in particular to transceiver antenna elements and can be used in pass-through phased array antennas (PAR) of the microwave range with electric beam scanning. The technical result is the reduction of microwave energy losses in the antenna element of the passing headlamp. The antenna element of the pass-through headlamp 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. 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. A cylindrical ferrite rod and dielectric emitters are enclosed in a common segment of a metallized circular waveguide. The cylindrical ferrite rod and dielectric emitters are made of materials with a high dielectric constant of equal or close value to each other. 3 s.p. f-ly, 4 ill.

Description

The invention relates to antenna technology, in particular to transceiver antenna elements and can be used in pass-through phased array antennas (PAR) of the microwave range with electric beam scanning.

Known transceiver element of a phased antenna array 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 winding, while between the ends of the cylindrical ferrite rod and dielectric emitters matching dielectric washers are installed; a cylindrical ferrite rod, matching washers and dielectric emitters have the same diameter and are enclosed in a common segment of a metallized circular waveguide; on the surface of each of the dielectric emitters located outside the common segment of the metallized circular waveguide, a cone-shaped circumferentially closed groove is made on the surface of which a metallized coating is applied; two longitudinal diametrically located slots are made in the walls of a common segment of a metallized circular waveguide adjacent to a cylindrical ferrite rod; the magnetic circuit is made in the form of two U-shaped brackets, each of which contains a longitudinal plate located above the corresponding slot, and shoes resting on the surface of a common segment of a metallized round waveguide, and the bearing surface of the shoes is made in the shape of a circle of a common segment of a metallized round waveguide and has a groove made in its upper part along the axis of symmetry, the bearing surfaces of the shoes are ground with a high accuracy class and tightly pressed to the surface of the common metal segment round waveguide.

The cylindrical ferrite core is made of ferrite with a dielectric constant ε = 14 ÷ 17. Matching washers are made of material, for example, ceramic, with a dielectric constant of ε = 9 ÷ 11. Dielectric emitters are made of a material, for example, ceramic, with a dielectric constant ε = 7.15-7.35. The lengths of dielectric emitters are selected from the condition of providing the required mechanical strength and stiffness of the antenna system web. The free ends of dielectric emitters have a conical or cylindrical shape [1].

The reason that impedes the achievement of the following technical result

when using the known transceiver element PAR, is as follows. The presence of joints between a cylindrical ferrite rod, dielectric matching washers and emitters reduces the transmission coefficient of the electromagnetic wave through the element and the gain of the PAR in general due to the loss of microwave energy due to its internal reflections at the joints. In addition, the use of three materials with different dielectric constants, the grooves on the surfaces of dielectric emitters to reduce the reflections of microwave waves from the ends of a common segment of a metallized circular waveguide and improve the alignment of dielectric emitters with space complicate the design of the device and increase the complexity and cost of its production.

The essence of the utility model is as follows. The task to which it is aimed is to reduce the complexity and cost of production of the antenna element of the HEADLIGHT by simplifying its design. The technical result achieved by the implementation of the utility model is expressed in reducing the loss of microwave energy in the antenna element of the pass-through headlamp.

The specified technical result is achieved by the fact that in the known transceiver element PAR, 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 winding, a cylindrical ferrite rod and dielectric emitters are enclosed in a common segment of a metallized round waveguide, according to the invention, a cylindrical ferrite rod and dielectric emitters are made of materials with a high dielectric constant, identical or close to each other, dielectric emitters contain a cylindrical part and are rigidly connected to the ends of a cylindrical ferrite rod by one end, and elongations in the form of truncated cones are made on their other ends, and the base diameter of the truncated cones is less than the diameter the cylindrical part of the dielectric emitter.

The ends of the common segment of a metallized circular waveguide are at a distance of (0.05-0.1) λ ₀ from the base of the truncated cones.

The height of the truncated cones is (0.8-1.2) λ ₀ , where λ ₀ is the center wavelength of the 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.

The causal relationship between the essential features and the technical result is expressed in the fact that, due to the implementation of the ferrite rod and emitters from materials with high equal or close in value dielectric

permeability, reducing the number of joints due to the exclusion of matching washer transformers, as well as the difference in the diameters of the cylindrical and conical parts of the emitters, the matching of the antenna element with space is improved, which reduces the loss of microwave energy and, accordingly, increases the gain of the pass-through headlamp.

The utility model is illustrated by drawings, in which are presented: figure 1 - design of the antenna element of the passage HEADLIGHT; figure 2 is a side view along arrow A of figure 1; figure 3 is a graph of the difference in the gain of the pass-through headlamps containing the claimed and known antenna elements; figure 4 - depending on the frequency of the coefficients of ellipticity of the claimed and known antenna elements.

The antenna element of the passable PAR (Fig. 1) contains a phase shifter consisting of a magnetizing winding 2 located inside the magnetic circuit 1, in which a cylindrical ferrite rod 3 is installed, and two dielectric emitters 4, 5. The cylindrical ferrite rod 3 is made of ferrite with a high dielectric constant of the order ε = 14-17, for example, from ferrite grade 3SCh-18 (YK7.074.076TU) with ε = 16. The dielectric emitters 4, 5 have cylindrical and conical parts and are made of a material also having a high dielectric constant of the order of ε = 14-17, for example, of the MT-16 ceramic material with ε = 16 [2]. The cylindrical ferrite rod 3 and the cylindrical parts of the dielectric emitters 4, 5 are made with the same diameter, their ends are rigidly interconnected, for example with glue, and enclosed in a common segment of a circular metallized waveguide 6. The waveguide can be obtained by sputtering or galvanic deposition of a metal layer , for example, copper, 1.1-1.5 μm thick on the surface of a cylindrical ferrite rod 3 and most of the cylindrical surface of dielectric emitters 4, 5. The free end parts of the latter they are in the form of truncated cones, which may be formed during casting of the dielectric radiator, or by machining it. The height L of the truncated cones is (0.8-1.2) λ ₀ , where λ ₀ is the central wavelength of the 10 percent range, the diameter d _{2 of} their bases is less than the diameter d _{1 of the} cylindrical part of the dielectric emitters 4, 5 (Fig 4) and is (0.8-0.9) d ₁ , and the diameter d _{3 of} its peak is (0.5-0.6) d ₁ . The total length of the metallized circular waveguide 4 on the cylindrical part of the dielectric emitters 4, 5 ends at a distance S = (0.05-0.1) λ ₀ from the base of the truncated cones. The lengths of the cylindrical parts of the dielectric emitters 4, 5 can be equal or different depending on the design features of the through-beam headlamp and are determined from the condition of ensuring the required mechanical strength and stiffness of the web

antennas, as well as the possibility of placing in it control devices for transceiving elements and heat removal, for example, pipelines of a purge system with compressed air or a system with liquid refrigerant. The maximum diameter of the base d _{2 of the} truncated cone and the minimum diameter of its apex d ₃ are chosen by calculation from the condition of good excitation of the surface wave in it, minimization of microwave energy reflections at the “waveguide-emitter” junction and matching of the dielectric emitters 4, 5 of the emitter with space.

Phaser can be performed according to known rules [1]. In particular, the magnetizing winding 2 of the control coil is wound on a paper frame and worn on a cylindrical ferrite rod 3, located above the slots in the walls of a common segment of a metallized circular waveguide 6. The terminals of the magnetizing winding 2 are connected to the antenna element control system (not shown in the drawing). On top of the magnetizing winding 2 are two magnetic cores 1, made in the form of U-shaped staples, each of which contains a longitudinal plate and shoes. The inner surface of the longitudinal plates has a cylindrical shape. The supporting surfaces of the shoes are made in the shape of a circle of a common segment of a metallized circular waveguide 6. A groove is made in the upper part of the supporting surface of the shoes along the symmetry axis to ensure the azimuthal symmetry of the magnetizing magnetic field, which reduces the resonance peaks of microwave energy loss at higher types of waves. The longitudinal plates of the U-shaped brackets are located above the slots in the walls of the common segment of the metallized round waveguide 6. Using a bandage (for example, a strong filament impregnated with varnish), the supporting surfaces of the shoes, which must be sanded with a high accuracy class, are tightly pressed to the side surface of the general segment of the metallized circular waveguide 6 so that the gap between them does not exceed 30 microns. Magnetic cores are made of a material with a low coercive force of the order of 0.35 oersted.

The described antenna element of the phased array operates as follows. In the transmission mode, microwave energy with a circular polarization wave from the PAR illuminator falls on the first radiator of the element, for example, a truncated cone 4, passes inside it and propagates along its cylindrical part and cylindrical ferrite rod 3 inside a common segment of a metallized waveguide 6. Passing through a phase shifter, the electromagnetic wave receives a certain phase shift depending on the duration of the voltage pulses supplied to the magnetizing winding 2 from the control system of the PAR elements. Propagating further, the electromagnetic wave hits the second emitter 5 and is transmitted through space to the truncated one. After the end of the action of voltage pulses, the magnetic system of the phase shifter remembers this state and phase

the shift will remain until the next magnetization reversal cycle. When taken, the process proceeds in the reverse order.

As follows from the graph of figure 3, which shows the dependence on the relative frequency f / f ₀ , where f ₀ is the center frequency of the range, the difference of the gain ΔG of the phased antenna arrays with the claimed and known antenna elements, the gain of the PAR, recruited from prototypes of the claimed antenna element, in 90% of the specified frequency range significantly, up to 1.4 dB, exceeds the same indicator of the PAR, containing antenna elements taken as a prototype. The claimed antenna element also provides a significant, at least 0.8 dB, gain in the ellipticity coefficient of the electromagnetic field. This is confirmed by the graphs of figure 4, which shows the dependence on the relative frequency f / f _{0 of} the ellipticity coefficients K _e (the ratio of the axes of the polarization ellipse) of the claimed antenna element and prototype. These experimental data indicate a decrease in the loss of microwave energy in the claimed transceiver antenna element in comparison with the prototype.

Information sources:

1. RU 2184410, H 01 Q 21 \ 00, H 01 P 1/19, 2002.

2. Catalog "Microwave and dielectric materials." OJSC Magneton Plant, St. Petersburg, 2001.

Claims (4)

1. The antenna element of the passage phased antenna array 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 winding, a cylindrical ferrite rod and dielectric emitters are enclosed in a common segment of a metallized circular waveguide, characterized in that a cylindrical ferrite rod and dielectric emitters are made of materials with high identical With a dielectric constant close to each other or close to each other, dielectric emitters contain a cylindrical part and are rigidly connected to the ends of a cylindrical ferrite rod by one end, and elongations in the form of truncated cones are made on their other ends, and the diameter of the base of the truncated cones is less than the diameter of the cylindrical part of the dielectric emitter. 2. The antenna element according to claim 1, characterized in that the ends of the common 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. 3. The antenna element according to claim 1, characterized in that the height of the truncated cones is (0.8-1.2) λ ₀ , where λ ₀ is the center wavelength of the 10 percent range. 4. The antenna element according to claim 1, characterized in that 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.