Design of the strength frame of the aerodynamic rudder using the topological optimization method

Q3 Earth and Planetary Sciences Aerospace Systems Pub Date : 2023-06-25 DOI:10.1007/s42401-023-00233-6
Yanina A. Kupriyanova, Sergey G. Parafes’
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Abstract

An algorithm for designing a structural and technological solution of the aerodynamic rudder of an unmanned aerial vehicle (UAV) is proposed. The purpose of the work is to form the strength frame of the rudder with subsequent refinement taking into account technological limitations. The algorithm is based on the application of the topological optimization method for case of maximizing the static rigidity of the rudder structure with a volume restriction. For optimization, a rudder structure finite element model is created, boundary conditions and load are determined for two calculated cases. As a result of topological optimization, a constructive strength scheme of the rudder is obtained. To verify the study, calculations of the stress–strain state and natural vibration frequencies of the rudder structure are completed. Calculations of the stress–strain state, modal analysis and topological optimization are performed in the environment of the ANSYS Workbench 19.2 software package. Based on the optimization results, a rudder structure is designed that meets technological constraints and strength requirements.

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利用拓扑优化法设计空气动力舵的强度框架
本文提出了一种无人驾驶飞行器(UAV)气动尾舵结构和技术解决方案的设计算法。这项工作的目的是形成方向舵的强度框架,并在考虑到技术限制的情况下进行后续改进。该算法基于拓扑优化方法的应用,用于在体积受限的情况下最大化方向舵结构的静态刚度。为进行优化,创建了舵结构有限元模型,并确定了两种计算情况下的边界条件和载荷。拓扑优化的结果是获得了舵的结构强度方案。为了验证研究结果,还完成了舵结构的应力应变状态和自然振动频率的计算。应力应变状态计算、模态分析和拓扑优化都是在 ANSYS Workbench 19.2 软件包环境下进行的。根据优化结果,设计出了符合技术限制和强度要求的舵结构。
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来源期刊
Aerospace Systems
Aerospace Systems Social Sciences-Social Sciences (miscellaneous)
CiteScore
1.80
自引率
0.00%
发文量
53
期刊介绍: Aerospace Systems provides an international, peer-reviewed forum which focuses on system-level research and development regarding aeronautics and astronautics. The journal emphasizes the unique role and increasing importance of informatics on aerospace. It fills a gap in current publishing coverage from outer space vehicles to atmospheric vehicles by highlighting interdisciplinary science, technology and engineering. Potential topics include, but are not limited to: Trans-space vehicle systems design and integration Air vehicle systems Space vehicle systems Near-space vehicle systems Aerospace robotics and unmanned system Communication, navigation and surveillance Aerodynamics and aircraft design Dynamics and control Aerospace propulsion Avionics system Opto-electronic system Air traffic management Earth observation Deep space exploration Bionic micro-aircraft/spacecraft Intelligent sensing and Information fusion
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