RU184782U1 - Device for absorbing electromagnetic radiation - Google Patents

Abstract

The invention relates to devices for absorbing electromagnetic radiation, reducing the magnitude and / or power of the reflected signal from an electromagnetic wave in a wide frequency range, and can be used as a protective device to reduce the radar visibility of objects of various sizes and configurations. A radar absorbing material is applied onto the surface of the device’s substrate, containing a polymer binder, a powder filler in the form of a multicomponent mixture, the particles of which are spherical in shape, and whiskers of a silicon carbide single crystal. The multicomponent mixture contains silicon carbide, molybdenum carbide, tungsten carbide, molybdenum disilicide, tungsten silicide at a certain ratio of material components and particle diameters. Silicon carbide single crystal whiskers are made in the form of two specific sizes with a weight ratio of 2: 1. The technical result consists in the effective absorption of electromagnetic radiation at temperatures of a radar absorbing material up to 500 ° C. 2 tablets, 1 ill.

Description

The invention relates to devices for absorbing electromagnetic radiation, reducing the magnitude and / or power of the reflected signal from an electromagnetic wave in a wide frequency range, and can be used as a protective device to reduce the radar visibility of objects of various sizes and configurations.

Known radar absorbing material intended for application to a surface to be coated, containing a polymer binder and a magnetic filler in the form of powdered ferrite or iron in a certain ratio of components (RU 2107705, 1998).

Known anti-radar material intended for application to a surface to be coated, containing a polymer binder and a powdery filler, which is used as a three-component mixture, made up in a certain ratio of components (RU 2300832, 2007). In the known technical solution, the three-component mixture includes ferrite, carbonyl iron in the form of particles of a spherical shape and a mixture of fullerenes C-60 and C-70 in a certain ratio of components.

A common significant drawback of the known technical solutions is the use of magnetoelectric materials as a radar absorbing material, which allows to reduce radar visibility in a narrow range of absorbed frequencies (from 8 to 13 GHz), but at the same time increases the visibility in the infrared spectrum by increasing the temperature of the radar absorbing material deposited on the coated surface during the transition of a part of electromagnetic energy to heat. In addition, with increasing temperature above 100 ° C, there is a significant decrease in the absorption of electromagnetic energy.

Known radar absorbing material intended for application directly to the surface of the protected object and / or on a flexible electrically conductive base containing a polymeric binder, a filler in the form of a mixture of powdered ferrite and carbonyl iron, made in the form of particles of a spherical shape, a mixture of fullerenes C-60 and C-70 and carbon nanotubes made in the form of multilayer straightened tubes of a certain diameter for a given ratio of components (RU 2482149, 2013). A disadvantage of the known technical solution is a narrow range of absorbed frequencies (from 2 to 20 GHz), and a decrease in radio absorbing properties with increasing temperature deposited on the surface of the absorbing material.

The closest in technical essence and purpose to the claimed utility model is a device for absorbing electromagnetic radiation, containing a substrate with a radar absorbing material deposited on its surface, including a polymer binder and a powder filler composed in a certain ratio in the form of a multicomponent mixture, the particles of which have a spherical shape (RU 162226, 2016). In the known technical solution, a three-component mixture of spherical particles of a certain particle size distribution is used as a powder filler, with zirconium carbide, zirconium oxide and astralen being used as components. Known technical solution reduces the likelihood of detection or classification of an object in an extended range of absorbed frequencies (up to 40 GHz). A significant disadvantage of the known technical solution is to reduce the level and / or power of the reflected wave at a working temperature of the material above 65 ° C.

The technical problem, the solution of which is provided by the implementation of the claimed utility model, is the need to increase the efficiency of absorption of electromagnetic radiation at a working temperature of the radar absorbing material of the device above 65 ° C.

The technical result achieved by the implementation of the proposed utility model is to ensure effective absorption of electromagnetic radiation at temperatures of radar absorbing material up to 500 ° C.

The claimed technical result is achieved due to the fact that in the device for absorbing electromagnetic radiation containing a substrate with a radar absorbing material deposited on its surface, including a polymer binder and a powder filler composed in a certain ratio in the form of a multicomponent mixture, the particles of which have a spherical shape, the radar absorbing material is additionally includes whiskers of a single crystal of silicon carbide, and the multicomponent mixture contains silicon carbide, molybdenum carbide, carbide tungsten, molybdenum disilicide, tungsten silicide in the following ratio of material components, wt.%:

polymer binder 25-35 silicon carbide 35-40 molybdenum carbide 6-10 Wolfram carbide 3-5 molybdenum disilicide 5-10 tungsten silicide 3-5 silicon carbide single crystal whiskers 8-10,

and the particle diameters of the multicomponent mixture are:

silicon carbide from 10 to 15 microns molybdenum carbide from 10 to 15 microns Wolfram carbide 5 to 10 microns molybdenum disilicide from 3 to 5 microns tungsten silicide from 1 to 3 microns,

and whiskers of a silicon carbide single crystal are made in the form of two sizes: a diameter of 5 μm and a length of 300 μm, and a diameter of 1 μm and a length of 10 mm with their weight ratio of 2: 1.

The significance of the distinguishing features of the utility model is confirmed by the fact that only the totality of all the features describing the utility model can provide a solution to the technical problem posed with achieving the claimed technical result.

The proposed technical solution is illustrated by the following detailed description of the device for absorbing electromagnetic radiation with reference to the figure, where the graph shows the dependence of the decrease in the level and / or power of the reflected wave of electromagnetic radiation on temperature in the frequency range from 10 to 40 GHz.

A device for absorbing electromagnetic radiation contains a substrate with a radar absorbing material deposited on its surface, including a polymer binder and a powder filler composed in a certain ratio in the form of a multicomponent mixture, the particles of which have a spherical shape. The radar absorbing material further includes silicon carbide single crystal whiskers. The multicomponent mixture contains silicon carbide, molybdenum carbide, tungsten carbide, molybdenum disilicide, tungsten silicide in the following ratio of material components, wt.%:

polymer binder 25-35 silicon carbide 35-40 molybdenum carbide 6-10 Wolfram carbide 3-5 molybdenum disilicide 5-10 tungsten silicide 3-5 silicon carbide single crystal whiskers 8-10

The particle diameters of the multicomponent mixture are:

silicon carbide from 10 to 15 microns molybdenum carbide from 10 to 15 microns Wolfram carbide 5 to 10 microns molybdenum disilicide from 3 to 5 microns tungsten silicide from 1 to 3 microns

In this case, the whiskers of a single crystal of silicon carbide are made in the form of two sizes: a diameter of 5 μm and a length of 300 μm, and a diameter of 1 μm and a length of 10 mm with their weight ratio of 2: 1.

As a polymer binder, heat-resistant polyfunctional epoxy resins based on novolacs, aminophenols, diaminodiphenylmethane, dicyclopentadiene of industrial brands ENFB (TU 1-596-36-2005), UP-2227 (TU 6-05-241-416-90) can be used, EDT-69N (TU 1-595-12-584-2006).

To ensure a technical result, the percentage of components of the radar absorbing material is critical.

The use of tungsten carbide and silicide, respectively, within the indicated limits ensures the operability of the radar absorbing material in the frequency range from 10 to 40 GHz at temperatures up to 500 ° C. The use of silicon carbide, carbide and molybdenum disilicide increases crack resistance and adhesive properties of the radar absorbing material. The use of whiskers of a single crystal of silicon carbide increases the strength and toughness of the radar absorbing material. Reducing the lower limits of the content of these components does not ensure the achievement of a technical result, and their use within the above does not provide a further increase in the efficiency of the device when the temperature rises above 500 ° C and leads to a rise in the cost of radar absorbing material. In addition, an increase in the content of tungsten carbide and silicide leads to an increase in brittleness and a decrease in the adhesive properties of the radar absorbing material.

Radar absorbing material is made by mixing the components immediately before applying it to the coated surface of the device substrate. Depending on the required value of reducing the level and / or power of the reflected electromagnetic wave, make up the corresponding ratio of the components of the material.

A device for absorbing electromagnetic radiation works as follows.

The compounds and structures of different particle size distribution used in the radar absorbing material contribute to a decrease in the reflection coefficient as a result of the effect of interference and diffraction. In addition, the possibility of reducing the level and / or power of the electromagnetic wave reflected by the external surface is associated with the use of materials with high values of dielectric and magnetic permeability, as a result of which periodic, so-called chiral conductive structures are created in the upper layers that cooperatively interact with electromagnetic radiation. The directional pattern of the propagating energy should be two-dimensional and lie in the plane of the reflecting material. In this case, to reduce reflection from flat conductive elements, the area occupied by such structures should be minimal, which fully corresponds to the geometrical structure of the whisker of a silicon carbide single crystal, which is an analog of an over-directional antenna with high radiation quality.

To assess the radar absorbing properties, tests were carried out on a device for absorbing electromagnetic radiation with a radar absorbing material deposited on its substrate at various ratios of its components, wt.% (See table No. 1):

To determine the decrease in the level and / or power of the reflected electromagnetic wave, a layer of radio-absorbing material with a thickness of 2.0 mm was applied to the substrate in accordance with the above formulations 1-3.

Experimental studies of the proposed device were carried out in the frequency range of electromagnetic radiation from 10 to 40 GHz. The figure shows a graph that displays the dependence of the decrease in the level and / or power of the reflected wave of electromagnetic radiation from temperature in the frequency range from 10 to 40 GHz.

The test results of the device, the radar absorbing material of which corresponds to formulations 1-3, are presented below (see table No. 2). For comparison, table No. 2 shows the test data of the radar absorbing material of the known technical solution (RU 162226, 2016) at an operating temperature of 50 ° C to 65 ° C.

An analysis of the data known and obtained as a result of experimental studies showed the following:

- in the frequency range from 10 to 18 GHz and at a temperature of the working surface from 300 ° C to 500 ° C, it is preferable to use the formulation 1;

- in the frequency range from 18 to 40 GHz and at a temperature of the working surface from 300 ° C to 500 ° C, the use of formulation 2 is preferred.

Also, the test results of the device, the radar absorbing material of which corresponds to formulations 1-3, showed that in the range of radiation frequencies from 18 to 25 GHz, a maximum decrease in the level and / or power of the electromagnetic wave reflected by the external surface is achieved, which is:

- 25 dB (recipe 1), 27 dB (recipe 3) and 29 dB (recipe 2) at a temperature of 50 ° C to 100 ° C, which is similar to the data of the known technical solution (RU 162226, 2016), indicated as the closest analogue (from 24 to 29 dB at a temperature of from 50 ° C to 65 ° C);

- from 33 dB (formulation 1) to 37 dB (formulation 2) at a temperature of 500 ° C.

Thus, the device for absorbing electromagnetic radiation allows for efficient absorption of electromagnetic radiation at temperatures of the radio-absorbing material up to 500 ° C in the indicated frequency range.

Claims (5)

A device for absorbing electromagnetic radiation, comprising a substrate with a radar absorbing material deposited on its surface, including a polymer binder and a powder filler composed in a certain ratio in the form of a multicomponent mixture, the particles of which are spherical in shape, characterized in that the radar absorbing material further includes silicon carbide single crystal whiskers, and the multicomponent mixture contains silicon carbide, molybdenum carbide, tungsten carbide, molybdenum disilicide, silicide frama the following component ratio of material, wt. %: polymer binder 25-35 silicon carbide 35-40 molybdenum carbide 6-10 Wolfram carbide 3-5 molybdenum disilicide 5-10 tungsten silicide 3-5 silicon carbide single crystal whiskers 8-10, and the particle diameters of the multicomponent mixture are: silicon carbide from 10 to 15 microns molybdenum carbide from 10 to 15 microns Wolfram carbide 5 to 10 microns molybdenum disilicide from 3 to 5 microns tungsten silicide from 1 to 3 microns, and whiskers of a silicon carbide single crystal are made in the form of two sizes: a diameter of 5 μm and a length of 300 μm, and a diameter of 1 μm and a length of 10 mm with their weight ratio of 2: 1.

Images