材料科学
复合材料
复合数
极限抗拉强度
硅橡胶
织物
空气动力学
翼
气动加热
变形(气象学)
碳纤维
天然橡胶
硫化
热的
压力(语言学)
工作(物理)
热稳定性
机制(生物学)
高超音速飞行
机械负荷
失效机理
空气动力
硅酮
先进复合材料
各向异性
变形机理
气动弹性
灾难性故障
动载荷
比模量
作者
Jiandong Huang,Jie Mei,Hui Feng Ning,Yue Zhuo,Hanxiang Shan,Fanfu Meng,Xueqi Jiang
出处
期刊:Polymers
[Multidisciplinary Digital Publishing Institute]
日期:2026-01-29
卷期号:18 (3): 358-358
标识
DOI:10.3390/polym18030358
摘要
To optimize the aerodynamic performance of the aircraft across its entire cross-section, wing shape control must be maintained based on flight operating conditions. A high-temperature flexible textile composite, which is the key to achieving the deformation of an aircraft wing, is urgently required in the deformable structure of high-speed aircraft. In this work, a novel type of flexible textile composite with enhanced temperature resistance was fabricated by plain-woven carbon fibers coated with silicone rubber. The material testing was carried out in a wind tunnel to simulate both the harsh temperature field distribution and the mechanical loads caused by aerodynamic forces under the flight profile. For the first time, temperatures exceeding 1000 °C were attained on the windward side of an aircraft wing with a peak recorded temperature of 1600 °C. The failure mechanisms of the flexible composites are revealed, and the thermal stability of the composites is evaluated. The results show that the significant tensile anisotropy in the flexible composites is along different off-axis angles, and the failure modes also change with the off-axis angle. The material does not show significant high-temperature oxidation ablation under thermo-mechanical coupling. This work reveals that under the triple action of such high temperatures, stress caused by wing surface tensioning, and the mechanical load caused by aerodynamic forces, the failure mechanism of the flexible textile composite is dominated by the mechanical load at high temperatures rather than by thermal instability, as is conventionally claimed.
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