Antonio Chiariello, Gaetano Perillo, Mauro Linari, Raffaele Russo, S. Orlando, Pasquale Vitale, M. Belardo
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引用次数: 0
摘要
本研究探讨了后屈曲行为分析在航空复合材料结构设计中的关键作用。传统的工程实践往往会导致复合材料部件过大,增加结构重量。EASA AMC 20-29 的 "积木式方法 "建议进行分阶段测试,但由于时间和成本方面的挑战,有必要转向高保真的后屈曲分析,MSC NASTRAN SOL 400 就是一个例子。下一代民用倾转旋翼机技术演示器机翼(NGTCTR-TD)的分析展示了这种方法,它有效地消除了静态测试的风险,有助于提高认证过程的效率。这项研究展示了先进的模拟如何详细揭示局部屈曲现象,从而进行精确的应力分布分析。这些分析消除了结构失效的风险,为实现更安全、更高效和更具成本效益的机身结构铺平了道路。未来的发展目标是用实验数据验证数值分析,进一步强调高保真模拟的可靠性和优势。
Virtual Full Scale Static Test of a Civil Tilt Rotor Composite Wing in Non-Linear Regime
This study addresses the crucial role of post-buckling behavior analysis in the structural design of composite aeronautical structures. Traditional engineering practices tend to result in oversized composite components, increasing structural weight. EASA AMC 20-29’s Building Block Approach suggests phased testing, but its time and cost challenges necessitate a shift to high-fidelity post-buckling analyses, exemplified by MSC NASTRAN SOL 400. This approach, showcased in the analysis of the Next Generation Civil Tilt Rotor Technology Demonstrator’s wing (NGTCTR-TD), effectively de-risks static tests, contributing to a more efficient certification process. The study demonstrates how advanced simulations provide detailed insights into local buckling phenomena, allowing precise stress distribution analysis. These analyses eliminate the risk of structural failure, paving the way for safer, more efficient, and cost-effective airframe structures. Future developments aim to validate numerical analyses with experimental data, further emphasizing the reliability and benefits of high-fidelity simulations.
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