RU2414029C1 - Electromagnetic wave absorber - Google Patents

Abstract

FIELD: radio engineering. ^ SUBSTANCE: in absorbing compound consisting of epoxy elastomeric binding agent there distributed is nanocrystalline powder representing particles of Fe-Cu-Nb-Si-B alloy with nanocrystalline structure, with size of particles of 1 to 50 mcm, which also contains nanocrystals of -(Fe, Si) compounds with volume density of (2.82.9)10-5 l/nm3, in the given formula in weight parts: epoxy elastomer - 100, hardener - 8, nanocrystalline powder - 300-600. ^ EFFECT: designing electromagnetic wave absorber for ultrabroadband antennae, which is operable in continuous band of ultrahigh, super high and extremely high frequencies, and its manufacturability is provided. ^ 2 dwg, 1 tbl

Description

The invention relates to the field of radio engineering, in particular to absorbers of electromagnetic waves, and can be used in ultra-wideband antennas operating in the continuous range of ultra-high (UHF), ultra-high (microwave) and extremely high (EHF) frequencies.

Electromagnetic wave absorbers are designed to absorb electromagnetic energy in the design of ultra-wideband antennas, reduce stray reflections from conductive objects located near the antennas, ensure the monotonic shape of the antenna radiation pattern, ensure the stability of the radio technical characteristics of the antennas along with the manufacturability of their manufacture in serial production.

For microwave technology, commercially available electromagnetic wave (PM) absorbers of the PM-3.2, PM-10, PM-24 brands containing carbonyl iron R-10 (TU 2531-002-10492330-2000 "PM magnetodielectric elastic plates are widely used "). The disadvantages of these absorbers are the instability of the reflection coefficient and the spread across the thickness of the plates supplied in finished form, for example, from 1.83 to 2.03 mm for PM-3.2 - actual data on the analysis of finished products, material loss due to machining of the plates, and the great complexity of manufacturing products having different surface curvatures.

Known composite material for protection against electromagnetic radiation (RF patent No. 2324989, 2006), consisting of a polymer base in which particles of the alloy Fe-Cu-Nb-Si-B or Co-Fe-Ni-Cu-Nb-Si are distributed -B with a nanocrystalline structure and a size of 1 to 100 microns. In this case, the alloy particles contain nanocrystals of compounds α- (Fe, Si) or ε-Co with a bulk density of (0.6 ÷ 1.4) · 10 ^-5 1 / nm ³ . The purpose of this technical solution is to increase the magnetic permeability µ and, as a consequence, increase the shielding coefficient. The technical solution does not contain information about the use of the specified composite material as radar absorbing. The article “Nanomaterials of a structural and functional class” (V. Rybin et al., “Questions of Materials Science”, 2006, No. 1 (45), pp. 169-178) indicates that the prospect of using nanocrystalline magnetic materials in creating radar absorbing materials (RPM) operating in the frequency range above 1 MHz is determined by the fact that at such frequencies the contribution to the magnetic properties of ferromagnets is not due to the displacement of the domain boundaries, but due to the rotation of the magnetization vectors, since in crystalline ferromagnets the dimensions of the domains are large, then the process of rotation of the magnetization vectors is difficult. Nanocrystalline magnetically soft alloys, which are a set of α-Fe or α- (Fe, Si) nanocrystals in a superparamagnetic state and located in a residual amorphous matrix, are devoid of these drawbacks. The high-frequency magnetic properties of these alloys will be determined by the rotation of the magnetization vectors of nanocrystals,

Known radar absorbing coating for antennas (RF patent No. 2369947, H01Q 1/38, 2009) based on epoxy elastomer and carbonyl iron, which has high adhesion, strength, manufacturability and acceptable radio technical characteristics. However, this technical solution is not used as a radar absorbing coating for ultra-wideband antennas.

The aim of this invention is to develop an electromagnetic wave absorber for ultra-wideband antennas, operable in the continuous range of ultra-high (UHF), ultra-high (microwave) and extremely high (EHF) frequencies along with the manufacturability of its manufacture.

This goal is achieved by the fact that in the absorbent composition, consisting of an epoxy-elastomeric binder, nanocrystalline powder is distributed, which consists of particles of an alloy Fe-Cu-Nb-Si-B with a nanocrystalline structure and a particle size of 1 to 50 μm with an alloy content in the particles nanocrystals of α- (Fe, Si) compounds with a bulk density of (2.8 ÷ 2.9) · 10 ^-5 1 / nm ³ in the following ratio in parts by weight:

epoxy elastomer one hundred hardener 8 nanocrystalline powder 300-600

Figure 1 shows the frequency dependence of the reflection coefficient of the absorber with a thickness of 0.02 λ with different contents of the mass parts of the nanocrystalline powder and the absorber from the radio-absorbing material grade PM-24.

Figure 2 shows the frequency dependence of the reflection coefficient of the absorber with a thickness of 0.12 λ with different contents of the mass parts of the nanocrystalline powder and the absorber from the radio-absorbing material grade PM-3.2.

The choice of polymer matrix is determined by operational and technological characteristics.

A change in the percentage of nanocrystalline powder in the developed absorbent composition with a thickness of, for example, 0.12 ÷ 0.02 λ, where λ is the wavelength for the range in which a particular absorber operates, made it possible to obtain the required absorption in extended sections of the working frequency range.

Comparative characteristics of the physicomechanical properties of the studied radar absorbing materials are given in the table.

Indicators PM-3.2 Radar Absorption Coating for Antennas EMC absorber with nanocrystalline powder Nominal specific gravity, g / cm ³ 2.84 2.72 2.98-3.49 Nominal thickness mm 1.83 1 ... 2 2 ... 6 Tensile strength, kgf / cm ² , not less 35 200 200 Permeability 1.23 1.15 0.65-4 The dielectric constant 10.21 11.07 12.5 ... 21

To check the radio technical characteristics, an absorbent composition 1 and an absorbent composition 2 were made with the following ratio of components, parts by weight:

Composition 1 Composition 2 epoxy elastomer one hundred one hundred hardener 8 8 nanocrystalline powder 300 60

Next, samples of absorbers with a thickness of 0.12 λ and 0.02 λ, respectively, were made and their radio-technical characteristics were checked.

The graphs of FIGS. 1 and 2 show the dependences of the reflection coefficient R (dB) on the frequency f (GHz) of absorbers with different contents of nanocrystalline powder and absorbers from radio-absorbing materials PM-24 and PM-3.2 in the lower and upper parts of the operating range frequencies of an ultra-wideband antenna.

From the graphs in figure 1 shows that the increase in mass.h. nanocrystalline powder in the composition of the samples of the absorber thickness, for example, 0.02 λ shifts the minimum of the reflection coefficient to the region of lower frequencies. The use of an absorber based on nanocrystalline powder with a content of 600 parts by weight As part of an ultra-wideband antenna, it allowed to expand its operating frequency range towards lower frequencies by 30% compared with the known absorber made of the PM-24 radio-absorbing material used in the antenna earlier.

From the graphs presented in figure 2, it is seen that the sample absorber thickness, for example, 0.12 λ with the content of nanocrystalline powder 300 mass.h. It has a minimum reflection coefficient at a frequency of 12.2 GHz, in contrast to samples from the radio-absorbing material PM-3.2 (A and B), which have a minimum reflection coefficient in the frequency range 8.5-10.7 GHz. The shift of the minimum of the reflection coefficient to the region of higher frequencies made it possible to ensure the monotonicity of the shape of the radiation pattern of an ultra-wideband antenna at frequencies of 11-12 GHz, which had gaps in the radiation patterns at the indicated frequencies when using the PM-3.2 radio-absorbing material.

Thus, when using absorbers containing nanocrystalline powder, in contrast to the known RPMs, the possibility of ensuring the monotonic shape of the radiation pattern and expanding the operating frequency range of the ultra-wideband antenna to higher and lower frequencies due to the use of a certain mass.h. nanocrystalline powder at the selected thickness of the absorbers.

The absorbent composition is made as follows: nanocrystalline powder is introduced into the epoxy-elastomeric binder, previously dried at a temperature of 120 ± 10 ° C for 1-2 hours in an oven, after which the mixture is thoroughly mixed. The resulting mixture is applied directly to the product, then placed in special molds that provide the required thickness of the absorber, the mold closes and is held at a normal temperature of 25 ± 10 ° C for 24 hours.

After removal from the mold, the products with the absorber are kept under normal conditions for at least 24 hours before testing. If necessary, the absorber may be machined.

Next, the following tests were carried out on antennas with an absorber containing nanocrystalline powder:

- verification of the radio technical characteristics of the antennas under normal conditions for compliance with technical requirements;

- a test for the effects of cyclic temperature changes at a temperature of -60 ° C - 2 hours, + 85 ° C - 2 hours, a total of 10 cycles;

- stability test when exposed to random vibration in the frequency range 5 - 2000 Hz with an average value of the total acceleration of 12.5 g;

- test for vibration resistance and vibration resistance in the frequency range of 5 - 2000 Hz with a test duration of 3 minutes (vibration resistance) and 9 hours (vibration resistance) along the x, y, z axes;

- a test for exposure to increased humidity of 96-100% at a temperature of + 35-55 ° C for 10 days;

- test for exposure to elevated temperature + 85 ° С - 2 h, + 120 ° С - 3 min;

- test for exposure to low temperature -60 ° C - 2 hours

After each type of test, the radio characteristics of the antennas were checked. The test results are positive.

Thus, the formulated problem of obtaining electromagnetic wave absorbers for ultrawideband antennas operating in the continuous range of ultrahigh (UHF), ultrahigh (microwave) and extremely high (EHF) frequencies has been solved.

The use of an electromagnetic wave absorber made in the form of a composite material with nanocrystalline powder, representing particles of an alloy Fe-Cu-Nb-Si-B with a nanocrystalline structure and a size of 1 to 50 μm with the content of α- (Fe, Si compounds in the nanocrystal particles of the alloy ) bulk density (2.8 ÷ 2.9) · 10 ^-5 1 / nm ³ based on epoxy-elastomeric binder, in antennas allowed:

- expand the operating frequency range of ultra-wideband antennas to 30% in the UHF region;

- to ensure the uniformity of the shape of the antenna patterns in the microwave and EHF;

- ensure the stability of the radio characteristics of the antennas;

- to improve the manufacturability of absorbers in antennas through the use of a progressive method of casting in the mold.

Claims (1)

An electromagnetic wave absorber, consisting of an epoxy-elastomeric binder, in which a magnetic filler is distributed, characterized in that a nanocrystalline powder is selected as a filler, which is particles of an alloy Fe-Cu-Nb-Si-B with a nanocrystalline structure and a particle size of from 1 to 50 μm containing nanocrystals of the compound α- (Fe, Si) with a bulk density (2.8 ÷ 2.9) · 10 ^-5 1 / nm ³ in the following ratio of the components of the absorber, wt.h .:
epoxy elastomer one hundred hardener 8 nanocrystalline powder 300 ÷ 600

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