RU2762691C1 - Radar-absorbing material (options) - Google Patents

Abstract

FIELD: radio-absorbing materials.

SUBSTANCE: invention relates to radio-absorbing materials (RAM), effective in the frequency range from 6 to 40 GHz, and can be used in those areas of technology where lightweight non-combustible radioprotective materials are required that are resistant to prolonged exposure to high temperatures. Two versions of RAM are proposed: RAM containing a dielectric binder polyalumochromophosphate and an electromagnetic radiation absorbing filler including hollow glass microspheres, soot and dispersed carbon fiber, with the following ratio of components, wt.%: polyalumochromophosphate - 54.5-58.0; hollow glass microspheres - 27-39; soot - 6-12; dispersed carbon fiber - 0-3, obtained by mixing the filler with an aqueous solution of alumochromophosphate at a mass ratio of alumochromophosphate/water = 1:2-2.2, followed by curing; RAM containing a dielectric binder - a product of the interaction of aluminoborophosphate and sodium tetraborate, and an electromagnetic radiation absorbing filler, including hollow glass microspheres, soot and dispersed carbon fiber, with the following ratio of components, wt.%: polyaluminium borophosphate - 42-49; sodium tetraborate - 12-2 0; hollow glass microspheres - 23.9-38.4; soot - 6-10; dispersed carbon fiber - 0-3, obtained by mixing a filler and sodium tetraborate with an aqueous solution of aluminoborophosphate at a mass ratio of aluminoborophosphate/water = 1: 2-2.2, followed by curing.

EFFECT: creation of a RAM (options) characterized by fire resistance (flammability class NF), high thermal resistance and low density (no more than 0.2 g/cm³), as well as environmentally friendly, absorbing electromagnetic radiation in a wide range of microwave waves.

4 cl, 1 dwg, 1 tbl

Description

The invention relates to radio-absorbing materials (RFM), effective in the frequency range from 6 to 40 GHz, and can be used in those areas of technology where lightweight non-combustible radioprotective materials are required that are resistant to prolonged exposure to high temperatures.

The most widely known RPMs are based on a polymeric organic binder, which serves as a matrix for uniform distribution of radio-absorbing substances in the bulk of the material. Most often, technical carbon, soot, graphite, carbonyl iron, and ferrites are used as radio-absorbing substances.

Known RPMs based on polyurethane foam containing as an electrically conductive filler carbon black (RU 2275719) or carbon fiber (RU 2410777). The disadvantages of these materials are flammability, released during thermal exposure to harmful gaseous products, a relatively high specific gravity (0.35-0.40 g / cm ³ ).

Known RPM containing as a dielectric binder polysiloxane (oligophenylsilsesquioxanedimethylsiloxane), and as an electromagnetic radiation absorbing filler carbon fiber in the amount of 0.0001-1.0 vol. % and magnetic powder in the amount of 5-50 vol. %. Additionally, the material may contain glass microspheres in the amount of 30-65 vol. % (RU 2273925). The disadvantages of this known material are flammability, harmful gaseous products emitted during thermal exposure, and a high specific gravity due to the use of a powder magnetic filler.

A number of RPMs based on epoxy resin are known. As substances absorbing radio wave radiation, use is made of: a two-component powdery filler consisting of discrete carbon fibers and powdered carbonyl iron (RU 2500704); powder filler in the form of microgranules of polysilicic acid containing either ferrite, or copper, or fullerene C ₇₀ , evenly distributed in the volume of microgranules in the form of nanoclusters (RU 2355081); carbon nanotubes pretreated in a mixture of sulfuric and nitric acids (RU 2570003). The disadvantages of these RPMs are flammability, released during thermal exposure to harmful gaseous products, a high specific gravity when using a powder filler (not less than 1 g / cm ³ ), technological and environmental problems arising from the distribution in the volume of uncured epoxy resin, which is poisonous in this state. substance, fine carbon nanotubes and discrete carbon fibers. When carbon nanotubes are used as a filler, additional technological difficulties arise due to the need for their special preparation (processing in a mixture of sulfuric and nitric acids).

Known use for RPM as a dielectric binder foam glass - an environmentally friendly heat and sound insulating material used in construction. Foam glass is non-combustible and moisture resistant. Soot (RU 2494507), soot and nickel-zinc ferrite (RU 2110122), silicon carbide (RU 2375793), silicon carbide, graphite, ferrite and their mixtures (CN 1286474), waste of semiconductor production, consisting of gallium arsenide and silicon carbide (RU 2707656). The disadvantages of these RPMs based on foam glass are the relatively high specific gravity (up to 0.45 g / cm ³ ), the large required thickness of the foam glass - up to 350 mm, which is technologically unfeasible, since the maximum thickness of the block foam glass is 180 mm. To obtain higher values, the blocks of foam glass are glued together, which complicates the technology of obtaining RPM. The manufacturing process of RPM based on foam glass is carried out at high temperatures (920-930 ° C), which is accompanied by high energy consumption.

Closest to the proposed radar absorbing material is a radar absorbing material based on a curable epoxy compound, described in patent RU 2417491, IPC H01Q 17/00, publ. 04/27/2011 (prototype). RPM prototype contains a curable epoxy compound, granular carbon black and hollow polymer or glass microspheres in the following ratio of components, wt. %:

curable compound 60-77 technical carbon 20-30 hollow microspheres 3-10

The prototype material has good absorbing capacity, but it is combustible, emitting harmful gaseous products during thermal exposure, is characterized by a high specific gravity (1 g / cm ³ ), which reduces its efficiency, and the material manufacturing technology is based on the use of poisonous epoxy resin.

The objective of the present invention is to create an RPM (variants), which will differ in incombustibility (class NG), high thermal stability, the absence of degradation products under thermal exposure, low density - no more than 0.2 g / cm ³ , required radio characteristics and environmentally friendly manufacturing technology.

The solution to the task is achieved:

- the proposed radar absorbing material containing a dielectric binder and a filler including hollow glass microspheres and an electromagnetic radiation absorbing carbon product, which contains polyalumochromophosphate as a dielectric binder, soot and dispersed carbon fiber as a carbon product in the following ratio, wt. %:

polyalumochromophosphate 54.5-58.0 hollow glass microspheres 27-39 soot 6-12 dispersed carbon fiber 0-3

and obtained by mixing the filler with an aqueous solution of alumochromophosphate at a mass ratio of alumochromophosphate / water = 1: 2-2.2, followed by curing. The average size of the hollow glass microspheres is 65 µm.

- the proposed radio-absorbing material containing a dielectric binder and a filler, including hollow glass microspheres and a carbon product absorbing electromagnetic radiation, which contains the product of the interaction of aluminum borophosphate and sodium tetraborate as a dielectric binder, soot and dispersed carbon fiber as a carbon product with the following ratio of components, wt ... %:

polyalumoborophosphate 42-49 sodium tetraborate 12-20 hollow glass microspheres 23.9-38.4 soot 6-10 dispersed carbon fiber 0-3

and obtained by mixing the filler and sodium tetraborate with an aqueous solution of aluminoborophosphate at a mass ratio of aluminoborophosphate / water = 1: 2-2.2, followed by curing.

The average size of the hollow glass microspheres is 65 µm. A distinctive feature of the proposed RPM (options), in addition to fire resistance and high heat resistance, is the low specific density of the material (0.15-0.20 g / cm ³ ), which increases its efficiency. A decrease in the density of the RPM is achieved, firstly, by a significant increase in the content of hollow glass microspheres in the composition of the material and, secondly, by the use of a blowing agent in the production of RPM - water, which is added to the binder in the claimed amount and evaporates during curing by heating to 180 ° C, creating micropores. When the amount of water deviates from the optimal concentration, enlargement of the pores is observed, which worsens the characteristics of the material.

When the content of hollow glass microspheres in the composition of the proposed RPM is higher than 39 wt. % the radio technical characteristics of the material deteriorate. An increase in the average diameter of microspheres above 65 µm also degrades the properties of the PM.

To ensure the necessary radio technical characteristics, the soot content in the RPM must be at least 6 wt. %, an increase above 12 wt. % leads to an increase in the specific density of the material.

The introduction of carbon fiber strengthens the material and has a beneficial effect on radio-technical properties.

Polyalumoborophosphate is less moisture resistant than polyalumochromophosphate. To impart hydrophobic properties to the claimed RPM according to the second variant, sodium tetraborate is introduced into its composition. The amount of Na ₂ B ₄ O _{7 is} less than 12 wt. % does not lead to high hydrophobicity, and the introduction of more than 20 wt. % does not change properties.

Both versions of the proposed RPM are distinguished by fire resistance (oxygen index 100%), flammability class NG), heat resistance (> 800 ° C), and the absence of thermal degradation products when heated to 700 ° C.

The proposed RPM (options) is obtained as follows.

The oligomer of alumochromophosphate (AHPS, grade B-1) or aluminoborophosphate (ABPS, grade B) is diluted with water in a mass ratio of oligomer / water = 1: 2-2.2 and, with stirring, add carbon black (grade P366E), carbon fiber (FibARMFiber C) , hollow glass microspheres and sodium tetraborate when receiving the second version of the RPM, the mixture is placed in a mold, heated at a rate of 5 ° / min to 180 ° C and kept at 180 ° C for an hour. The composition and properties of the obtained RPM samples are shown in the table.

The proposed RPM (variants) can be obtained inside the shell or placed in a shell made of a reinforced composite based on phosphate binders (see Fig.), Or a heat-resistant protective layer based on phosphate, silicate or cement binders can be applied to the surface of the resulting material.

As can be seen from the above data, the claimed RPM (variants) is characterized by fire resistance, high thermal resistance and low density (no more than 0.2 g / cm ³ ). The material is environmentally friendly, undergoes mechanical processing, absorbs electromagnetic radiation in a wide range of microwave waves, the reflection coefficient of a pyramidal RPM 35 cm high at a normal incidence of radiation does not exceed 40 dB in the frequency range from 6 to 40 GHz.

The proposed RPM (options) is obtained using an environmentally friendly, simple and energy-saving technology using domestic materials and equipment.

Claims (8)

1. A radio-absorbing material containing a dielectric binder and a filler, including hollow glass microspheres and an electromagnetic radiation-absorbing carbon product, characterized in that it contains polyalumochromophosphate as a dielectric binder, soot and dispersed carbon fiber as a carbon product in the following ratio, wt. %: polyalumochromophosphate 54.5-58.0 hollow glass microspheres 27-39 soot 6-12 dispersed carbon fiber 0-3 and obtained by mixing the filler with an aqueous solution of alumochromophosphate at a mass ratio of alumochromophosphate / water = 1: 2-2.2, followed by curing. 2. Radar absorbing material according to claim 1, characterized in that the average size of the hollow glass microspheres is 65 microns. 3. A radio-absorbing material containing a dielectric binder and a filler, including hollow glass microspheres and a carbon product that absorbs electromagnetic radiation, characterized in that as a dielectric binder it contains the product of the interaction of aluminum borophosphate and sodium tetraborate, and as a carbon product, soot and dispersed carbon fiber at the following ratio of components, wt. %: polyalumoborophosphate 42-49 sodium tetraborate 12-20 hollow glass microspheres 23.9-38.4 soot 6-10 dispersed carbon fiber 0-3 and obtained by mixing the filler and sodium tetraborate with an aqueous solution of aluminoborophosphate at a mass ratio of aluminoborophosphate / water = 1: 2-2.2, followed by curing. 4. Radar absorbing material according to claim 3, characterized in that the average size of the hollow glass microspheres is 65 microns.

Images