Structural Design and Analysis of a Light Aircraft Wing

Journal of Karary University for Engineering and Science Pub Date : 2021-12-21 DOI:10.54388/jkues.v1i2.58

Hana Mohamed Almagzob, Tarik Hassan Elssoni, Abdulaziz AbdulMajid

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Abstract

The aim of this study is to perform structural design and analysis of a light aircraft wing. Both aerodynamic analysis and structural design of the wing are covered. The aerodynamic analysis is achieved by using Schrenks Approximation Method simulated in MATLAB to estimate the lift distribution. In addition, static stress analysis of the wing is carried out to compute the stresses at wing structure when subjected to the generated aerodynamic loads and thereby examine its structural reliability. The stresses are estimated by using the finite element software package MSC/NASTRAN/PATRAN. A maximum Von Mises stress of 135MPa is obtained which is less than the yield stress for aluminum alloy used in wing design. On the other hand, and based on the finite element model, a free-vibration analysis is performed for the whole model. The frequencies for the first three modes and the corresponding mode shapes are presented. The purpose of this study is to correlate and validate the finite element model against the modal test in preparation for further complex analysis. The finite element results have shown that the suggested wing configuration of the light aircraft is safe, with margins of safety equal to 1.33 which occurs at the root section.

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某轻型飞机机翼结构设计与分析

本研究的目的是对轻型飞机机翼进行结构设计和分析。包括机翼的气动分析和结构设计。气动分析采用MATLAB模拟的Schrenks近似法估计升力分布。另外，对机翼进行静应力分析，计算机翼结构在产生气动载荷作用下的应力，从而检验其结构可靠性。应力计算采用有限元软件MSC/NASTRAN/PATRAN进行。得到的最大Von Mises应力为135MPa，小于机翼铝合金的屈服应力。另一方面，在有限元模型的基础上，对整个模型进行了自由振动分析。给出了前三个模态的频率和相应的模态振型。本研究的目的是将有限元模型与模态试验相关联并进行验证，为进一步的复杂分析做准备。有限元计算结果表明，所建议的轻型飞机机翼结构是安全的，安全裕度为1.33，发生在根部。

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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Journal of Karary University for Engineering and Science

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