Comparative Study and Airspeed Sensitivity Analysis of Full-Wing Solar-Powered UAVs Using Rigid-Body, Multibody, and Rigid-Flexible Combo Models

IF 1.1 4区 工程技术 Q3 ENGINEERING, AEROSPACE
An Guo, Shanshan Mu, Zhou Zhou, Jiwei Tang
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引用次数: 0

Abstract

Solar-powered UAVs are characterized by large-scale, lightweight, and low airspeed, and changes in airspeed lead to wing deformation or stalling, which can easily induce serious flight accidents. A single dynamic model cannot accurately describe this feature, and this airspeed sensitivity can only be analyzed by integrating rigid-body, multirigid-body, and rigid-flexible combo models. This paper proposes a dynamic analysis method for a mixture of rigid-body, multirigid-body, and rigid-flexible combo models, considering the applicable airspeed ranges, computational costs, and structural deformation assumptions of the three models and comparing the differences of modes and responses at different airspeeds, and quantitatively analyzes the effects of airspeed on the motion, deformation, and coupling. The results show that appropriate increase of airspeed is beneficial to the stability of large-scale lightweight platforms, but when it is increased to more than two times the cruise speed, the structural deformation is coupled with the flight dynamic modes, leading to the deterioration of the overall dynamic response. Finally, a mixture of the three models at different airspeeds is proposed, which is necessary for future ultralarge-scale solar-powered UAVs.
使用刚体、多体和刚柔结合模型对全机翼太阳能无人机进行比较研究和空速敏感性分析
太阳能无人机具有体积大、重量轻、空速低等特点,空速变化会导致机翼变形或失速,容易诱发严重的飞行事故。单一的动力学模型无法准确描述这一特点,只有综合刚体、多刚体和刚柔结合模型才能分析这种空速敏感性。本文提出了刚体、多刚体和刚柔组合模型混合的动力学分析方法,综合考虑了三种模型的适用空速范围、计算成本和结构变形假设,比较了不同空速下的模态和响应差异,定量分析了空速对运动、变形和耦合的影响。结果表明,适当提高空速有利于大型轻型平台的稳定性,但当空速提高到巡航速度的两倍以上时,结构变形与飞行动力模态耦合,导致整体动力响应恶化。最后,提出了三种模型在不同空速下的混合模式,这对未来超大型太阳能无人机来说是必要的。
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
CiteScore
2.70
自引率
7.10%
发文量
195
审稿时长
22 weeks
期刊介绍: International Journal of Aerospace Engineering aims to serve the international aerospace engineering community through dissemination of scientific knowledge on practical engineering and design methodologies pertaining to aircraft and space vehicles. Original unpublished manuscripts are solicited on all areas of aerospace engineering including but not limited to: -Mechanics of materials and structures- Aerodynamics and fluid mechanics- Dynamics and control- Aeroacoustics- Aeroelasticity- Propulsion and combustion- Avionics and systems- Flight simulation and mechanics- Unmanned air vehicles (UAVs). Review articles on any of the above topics are also welcome.
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