Gust response of an elasto-flexible morphing wing using fluid–structure interaction simulations

IF 5.3 1区工程技术 Q1 ENGINEERING, AEROSPACE

Chinese Journal of Aeronautics Pub Date : 2023-12-13 DOI:10.1016/j.cja.2023.12.017

Jonathan PFLÜGER, Christian BREITSAMTER

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Abstract

Small and micro unmanned aircraft are the focus of scientific interest due to their wide range of applications. They often operate in a highly unstable flight environment where the application of new morphing wing technologies offers the opportunity to improve flight characteristics. The investigated concept comprises port and starboard adjustable wings, and an adaptive elasto-flexible membrane serves as the lifting surface. The focus is on the benefits of the deforming membrane during the impact of a one-minus-cosine type gust. At a low Reynolds number of Re = 264000, the morphing wing model is investigated numerically by unsteady fluid–structure interaction simulations. First, the numerical results are validated by experimental data from force and moment, flow field, and deformation measurements. Second, with the rigid wing as the baseline, the flexible case is investigated, focusing on the advantages of the elastic membrane. For all configurations studied, the maximum amplitude of the lift coefficient under gust load shows good agreement between the experimental and numerical results. During the decay of the gust, they differ more the higher the aspect ratio of the wing. When considering the flow field, the main differences are due to the separation behavior on the upper side of the wing. The flow reattaches earlier in the experiments than in the simulations, which explains the higher lift values observed in the former. Only at one intermediate configuration does the lift amplitude of the rigid configuration exceeds that of the flexible by about 12%, with the elastic membrane resulting in a smaller and more uniform peak load, which is also evident in the wing loading and hence in the root bending moment.

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利用流固相互作用模拟弹性变形翼的阵风响应

小型和微型无人驾驶飞机应用广泛，是科学界关注的焦点。它们通常在高度不稳定的飞行环境中工作，而新型变形机翼技术的应用为改善其飞行特性提供了机会。所研究的概念包括左舷和右舷可调机翼，以及作为升力面的自适应弹性薄膜。重点是变形膜在一减余弦型阵风影响下的益处。在 Re = 264000 的低雷诺数条件下，通过非稳定流固耦合模拟对变形翼模型进行了数值研究。首先，通过力和力矩、流场和变形测量的实验数据验证了数值结果。其次，以刚性机翼为基准，研究了柔性情况，重点关注弹性膜的优势。对于所研究的所有配置，阵风载荷下升力系数的最大振幅在实验结果和数值结果之间显示出良好的一致性。在阵风衰减期间，机翼长宽比越大，两者的差异越大。在考虑流场时，主要差异是由于机翼上侧的分离行为造成的。实验中的气流比模拟中的气流更早重新附着，这也是前者升力值更高的原因。只有在一个中间构型上，刚性构型的升力振幅比弹性构型高出约 12%，弹性膜产生的峰值载荷更小、更均匀，这在机翼载荷中也很明显，因此在根部弯矩中也很明显。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Chinese Journal of Aeronautics 工程技术-工程：宇航

CiteScore

10.00

自引率

17.50%

发文量

3080

审稿时长

55 days

期刊介绍： Chinese Journal of Aeronautics (CJA) is an open access, peer-reviewed international journal covering all aspects of aerospace engineering. The Journal reports the scientific and technological achievements and frontiers in aeronautic engineering and astronautic engineering, in both theory and practice, such as theoretical research articles, experiment ones, research notes, comprehensive reviews, technological briefs and other reports on the latest developments and everything related to the fields of aeronautics and astronautics, as well as those ground equipment concerned.