Positive and negative feedback of entangled lightning multiphysics on composites

被引：0

作者：

Wu, Yue ^{[1
]}

Wang, Fusheng ^{[1
]}

Lv, Chenyang ^{[1
]}

Sun, Jinru ^{[2
]}

Ma, Xiangteng ^{[3
]}

Huang, Chenguang ^{[1
]}

Fan, Zhiqiang ^{[1
]}

Wang, Shaozhen ^{[1
]}

Wang, Chenglin ^{[1
]}

Gao, Yunpeng ^{[1
]}

Duan, Zemin ^{[4
,5
]}

Yao, Xueling ^{[2
]}

机构：

[1] School of Mechanics, Civil Engineering and Architecture, Northwestern Polytechnical University, Xi'an

[2] State Key Laboratory of Electrical Insulation and Power Equipment, Xi'an Jiaotong University, Shaanxi, Xi'an

[3] Designing Institute of Hubei Aerospace Technology Academy, Wuhan

[4] Aviation Key Laboratory of Science and Technology on High Intensity Electromagnetic Environment Protection, Anhui

[5] Anhui Province Key Laboratory of Aircraft Lightning Protection, Anhui

来源：

International Journal of Mechanical Sciences | 2025年 / 290卷

基金：

中国国家自然科学基金;

关键词：

Composites; Damage mechanisms; Feedback system; Lightning strike; Multiphysics coupling;

D O I：

10.1016/j.ijmecsci.2025.110022

中图分类号：

学科分类号：

摘要：

Lightning strike will have intertwined multi-physical effects on carbon fiber reinforced polymer. According to experiments and high-fidelity simulations in this study, distinctive positive and negative feedback is originally identified between the entangled lightning effects in composites damage driving. The intricate mesoscopic feedback mechanisms are groundbreakingly revealed through the anisotropic equivalent circuit. Positive feedback exists between ablation and mechanical effects, while thermal strain is counteracted by overpressure and ampere force effects. These feedback relationships are formed due to dissimilar action mechanisms and energy transformations, which dynamically change with time and location. They jointly cause complex non-uniform damage to composites. © 2025 Elsevier Ltd

引用

共 88 条

[1] Yair Y., Lightning hazards to human societies in a changing climate, Environ Res Lett, 13, (2018)
[2] Hoole P., Hoole S., Introduction to lightning and lightning protection, Lightning engineering: physics, computer-based test-bed, protection of ground and airborne systems, pp. 1-50, (2022)
[3] Kossowski T., Kwiatkowski B., Mazur D., Bena L., Conka Z., Palfi J., Interference protection from lightning discharges associated with type of unmanned aerial vehicle shield, Measurement, 241, (2025)
[4] Delkowski M., Smith C.T.G., Anguita J.V., Silva S.R.P., Radiation and electrostatic resistance for ultra-stable polymer composites reinforced with carbon fibers, Sci Adv, 9, (2023)
[5] Fu Q.G., Zhang P., Zhuang L., Zhou L., Zhang J.P., Wang J., Hou X.H., Riedel R., Li H.J., Micro/nano multiscale reinforcing strategies toward extreme high-temperature applications: take carbon/carbon composites and their coatings as the examples, J Mater Sci Technol, 96, pp. 31-68, (2022)
[6] Wu S.J., Li H.J., Futaba D.N., Chen G.H., Chen C., Zhou K.C., Zhang Q.F., Li M., Ye Z.L., Xu M., Structural design and fabrication of multifunctional nanocarbon materials for extreme environmental applications, Adv Mater, 34, (2022)
[7] Candela Garolera A., Madsen S.F., Nissim M., Myers J.D., Holboell J., Lightning damage to wind turbine blades from wind farms in the US, IEEE Trans Power Deliv, 31, pp. 1043-1049, (2014)
[8] He H.X., Chen W.J., Luo B., Bian K., Xiang N.W., Yin Y., Zhang Z.H., Dai M., He T.Y., On the electrical breakdown of GFRP wind turbine blades due to direct lightning strokes, Renew Energy, 186, pp. 974-985, (2022)
[9] Andraud V., Martins R.S., Zaepffel C., Landfried R., Teste P., Lalande P., Physical properties of the swept arc channel in the context of lightning strikes to aircraft, J Phys D Appl Phys, 56, (2023)
[10] Kim Y.G., Jo J.H., Kim D.H., Lee H., Myong R.S., Effects of lightning on UAM aircraft: complex zoning and direct effects on composite prop-rotor blade, Aerosp Sci Technol, 124, (2022)

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