Sage Journals: Discover world-class research

Abstract

The main challenge in the design of radar-absorbing composite structures (RASs) is that there is a variety of different parameters affecting the absorbing performance. In this study, these parameters are categorized into: (1) reinforcing materials including fabric types (i.e., glass fabric, carbon fabric, and 3D fabric) and filler types (i.e., carbon black, carbonyl iron, and polyaniline); (2) geometric parameters including layer thickness and stacking sequences; and (3) manufacturing methods. Up to now, the effect of all these parameters has not been simultaneously investigated and optimized on the X-band radar-absorbing feature of composite structures. Therefore, the influence of all these parameters is first experimentally investigated using waveguide tests; then, a new multi-objective optimization algorithm based on NSGA II technique is developed to simultaneously optimize the effective parameters for high-performance RAS with maximum average reflection loss and minimum weight, while considering structural limitations. Finally, the proposed algorithm is evaluated by experimental results.

Keywords

electromagnetic waves composites radar-absorbing structure reflection loss multi-objective optimization

Get full access to this article

View all access options for this article.

References

Joshi

Athawale

. Electrically Conductive Silicone/Organic Polymer Composites. Silicon 2014; 6: 199–206.

Jayalakshmi

Inamdar

Anand

, et al. Polymer matrix composites as broadband radar absorbing structures for stealth aircrafts. J Appl Polym Sci 2018; 136: 1–21.

Kim

Lee

. Composite sandwich constructions for absorbing the electromagnetic waves. Compos Struct 2009; 87: 161–167.

Bahri-Laleh

Didehban

Yarahmadi

, et al. Microwave Absorption Properties of Polyaniline/Carbonyl Iron Composites. Silicon 2018; 10: 1337–1343.

Folgueras

Alves

Rezende

. Evaluation of a nanostructured microwave absorbent coating applied to a glass fiber/polyphenylene sulfide laminated composite. Mater Res 2014; 17: 197–202.

Choi

Jung

H-T

. A new triple-layered composite for high-performance broadband microwave absorption. Compos Struct 2015; 122: 166–171.

Magisetty

Raj

Datar

, et al. Nanocomposite engineered carbon fabric-mat as a passive metamaterial for stealth application. J Alloys Compd 2020; 848: 155771.

Pang

Duan

Huang

, et al. Research advances in composition, structure and mechanisms of microwave absorbing materials. Compos B Eng 2021; 224: 109173.

Wang

Zhang

Zhao

, et al. A novel MOF-drived self-decomposition strategy for CoO@N/C-Co/Ni-NiCo2O4 multi-heterostructure composite as high-performance electromagnetic wave absorbing materials. Chem Eng J 2021; 426: 131667.

10.

Adebayo

Soleimani

Guan

, et al. A simple route to prepare Fe3O4@C microspheres as electromagnetic wave absorbing material. J Mater Res Technol 2021; 12: 1552–1563.

11.

Wang

Murugadoss

Kong

, et al. Overview of carbon nanostructures and nanocomposites for electromagnetic wave shielding. Carbon N Y 2018; 140: 696–733.

12.

Kumar Chakradhary

Akhtar

. Absorption properties of CNF mixed cobalt nickel ferrite nanocomposite for radar and stealth applications. J Magn Magn Mater 2021; 525: 167592.

13.

Vasconcelos da Silva

Pezzin

Cerqueira Rezende

, et al. Glass fiber/carbon nanotubes/epoxy three-component composites as radar absorbing materials. Polym Compos 2016; 37: 2277–2284.

14.

Wang

Jiang

Yang

, et al. Carbon fiber enhanced mechanical and electromagnetic absorption properties of magnetic graphene-based film. Thin Solid Films 2019; 674: 97–102.

15.

Liang

Bai

, et al. Electromagnetic shielding property of carbon fiber felt made of different types of short-chopped carbon fibers. Compos A Appl Sci Manuf 2019; 121: 289–298.

16.

Pang

Wang

, et al. Carbon fiber assisted glass fabric composite materials for broadband radar cross section reduction. Compos Sci Technol 2018; 158: 19–25.

17.

Choi

Nam

Jang

, et al. Characteristics of silicon carbide fiber-reinforced composite for microwave absorbing structures. Compos Struct 2018; 202: 290–295.

18.

Kallumottakkal

Hussein

Iqbal

. Recent Progress of 2D Nanomaterials for Application on Microwave Absorption: A Comprehensive Study. Front Mater 2021; 8: 1–19.

19.

Lyu

Zhao

Hou

, et al. Electromagnetic interference shielding based on a high strength polyaniline-aramid nanocomposite. Compos Sci Technol 2017; 149: 159–165.

20.

Salimkhani

Palmeh

Khiabani

, et al. Electrophoretic deposition of spherical carbonyl iron particles on carbon fibers as a microwave absorbent composite. Surf Inter 2016; 5: 1–7.

21.

Deb

Pratap

Agarwal

, et al. A fast and elitist multiobjective genetic algorithm: NSGA-II. IEEE Trans Evol Comput 2002; 6: 182–197.

22.

De Castro Folgueras

Alves

Rezende

. Dielectric properties of microwave absorbing sheets produced with silicone and polyaniline. Mater Res 2010; 13: 197–201.

23.

Folgueras

L de C

Alves

Rezende

. Microwave absorbing paints and sheets based on carbonyl iron and polyaniline: Measurement and simulation of their properties. J Aerosp Technol Manag 2010; 2: 63–70.

24.

Jie

Gang

Mao-Sheng

. A novel method of computation and optimization for multi-layered radar absorbing coatings using open source software. Mater Des 2006; 27: 45–52.

25.

Goudos

. A versatile software tool for microwave planar radar absorbing materials design using global optimization algorithms. Mater Des 2007; 28: 2585–2595.

26.

Yang

X-S

. Genetic Algorithms. Nature-Inspired Optim Algorithms 2021; 1: 91–100.

Optimal design of broadband radar-absorbing composite structures based on different compositions,processing,and geometric parameters

Abstract

Keywords

Get full access to this article

References