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High-power-density microwave radiation resistant coating for radome and preparation method of high-power-density microwave radiation resistant coating

A technology of microwave radiation and power density, applied in coatings, epoxy resin coatings, etc., can solve problems such as coating peeling, chemical changes, and resin carbonization, and achieve both heat resistance and mechanical properties, and dielectric loss tangent The effect of small value and small coating temperature rise

Active Publication Date: 2015-07-22
NAT UNIV OF DEFENSE TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

When the temperature of the coating exceeds its service temperature, the resin in the coating will be carbonized, the color of the coating will turn yellow and become brittle, and in severe cases, the coating will fall off, which will affect the normal operation of the transmitting antenna
[0004] At present, general coatings mainly have defects such as chemical changes under high power density microwave radiation conditions, large dielectric loss tangent tgδ, and limited temperature resistance. These factors limit the application of coatings and make them unsuitable for airborne applications. use in environment

Method used

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  • High-power-density microwave radiation resistant coating for radome and preparation method of high-power-density microwave radiation resistant coating
  • High-power-density microwave radiation resistant coating for radome and preparation method of high-power-density microwave radiation resistant coating
  • High-power-density microwave radiation resistant coating for radome and preparation method of high-power-density microwave radiation resistant coating

Examples

Experimental program
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Effect test

Embodiment 1

[0035] a kind of likefigure 1 The radome of the present invention is shown as a coating resistant to high power density microwave radiation, and the coating can withstand a power density of 17.6W / cm 2 microwave radiation, the dielectric loss tangent of the coating is 3.7×10 -2 , the coating is directly adhered to the surface of the radome, and the outer layer of the coating can be coated with other topcoats, and the radome is made of fiber-reinforced plastic. The coating in this example is mainly prepared by mixing and curing component A and component B. Component A is mainly a mixture of silicone modified epoxy resin, boron nitride powder, mica powder, solvent and additives. , Component B is phenolic resin, the phenolic resin is the product obtained by chemical reaction of carboxy-terminated nitrile rubber. The particle size of the mica powder is 1000 mesh, and the particle size of the boron nitride powder is 800 mesh to 1500 mesh. The solvent is an equal proportion mixture...

Embodiment 2

[0043] A high power density microwave radiation resistant coating for a radome of the present invention, the coating can withstand a power density of 41W / cm 2 microwave radiation, the dielectric loss tangent of the coating is 3.8×10 -2 , the coating is directly adhered to the surface of the radome, and the outer layer of the coating can be coated with other topcoats, and the radome is made of fiber-reinforced ceramics. The coating in this example is mainly prepared by mixing and curing component A and component B. Component A is mainly a mixture of silicone modified epoxy resin, boron nitride powder, asbestos powder, solvent and additives. , Component B is phenolic resin, the phenolic resin is the product obtained by chemical reaction of carboxy-terminated nitrile rubber. The particle size of asbestos powder is 1500 mesh, and the particle size of boron nitride powder is 1500 mesh. The solvent is an equal proportion mixture of xylene, acetone, ethyl acetate, butanol and ethyl...

Embodiment 3

[0051] A high power density microwave radiation resistant coating for a radome of the present invention, the coating can withstand a power density of 80W / cm 2 microwave radiation, the dielectric loss tangent of the coating is 3.8×10 -2 , the coating is directly adhered to the surface of the radome, and the outer layer of the coating can be coated with other topcoats, and the radome is made of fiber-reinforced glass-ceramics. The coating in this example is mainly prepared by mixing and curing component A and component B. Component A is mainly a mixture of silicone modified epoxy resin, boron nitride powder, quartz powder, solvent and additives. , Component B is phenolic resin, the phenolic resin is the product obtained by chemical reaction of carboxy-terminated nitrile rubber. The particle size of the quartz powder is 2000 mesh, and the particle size of the boron nitride powder is 1500 mesh. The solvent is an equal proportion mixture of xylene, acetone and ethyl acetate. Aux...

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Abstract

The invention discloses a high-power-density microwave radiation resistant coating for a radome. The high-power-density microwave radiation resistant coating can bear the microwave radiation with the power density of 17.6-80.0 W / cm<2>; the dielectric loss angle tangent value of the coating is from 3.7*10<-2> to 3.8*10<-2>; the coating is directly adhered to the surface of the radome; a preparation method of the coating comprises the following steps: firstly mixing epoxy resin, boron nitride powder, mineral powder, a solvent and an auxiliary according to a ratio, refining the mixture through a ball milling process to obtain a component A, mixing the component A with phenolic acid according to a ratio, coating the surface of the radome material with the mixed coating, and heating and curing the radome material coated with the coating, so as to obtain the high-power-density microwave radiation resistant coating. The high-power-density microwave radiation resistant coating disclosed by the invention is low in dielectric loss tangent value, stable in performance, simple in preparation, and low in cost.

Description

technical field [0001] The invention belongs to the field of functional coatings, in particular to a microwave radiation-resistant coating for radome and a preparation method thereof. Background technique [0002] With the development of electronic countermeasures technology, the interference power is getting larger and larger. When applied to airborne equipment, the continuous transmission power of a single antenna can reach hundreds of watts or even kilowatts. According to the shape requirements of the aircraft, the transmitting antenna needs to be equipped with a rectifying radome. However, the rectenome is limited by the aerodynamic requirements of the carrier, and the degree of freedom in the design of the external dimension is small, resulting in a small distance between the radome and the antenna, and the space attenuation of high-power microwave is very small, so it is directly incident on the radome, and the inside of the radome The power density is quite high. Ac...

Claims

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Application Information

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IPC IPC(8): C09D163/00C09D161/14C09D7/12
CPCC08L2201/08C09D7/61C09D7/65C09D7/70C09D163/00C08L61/14C08K2003/385C08K3/34C08K7/12C08K3/36
Inventor 程海峰李俊生马青松刘海韬周永江张朝阳
Owner NAT UNIV OF DEFENSE TECH
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