Numerical two-dimensional optimization of a cylindrical fuselage for bioinspired unmanned aerial vehicle based on non-dominated sorting genetic algorithm-II

Bhushan Dewangan, H. Roy
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Abstract

To achieve an aerodynamically efficient design of fuselage for bioinspired unmanned aerial vehicles (UAV), the development of a systematic method is of paramount need. This work presents a multiobjective optimization study for shape parameterization of a 2D fuselage of foldable flapping wing UAV in low Reynolds number (2e05) flight conditions. The novelty of the research work lies in integrating S1223 airfoil characteristics for predicting the efficient shape design of the fuselage. This paper offers four sections; (i) the validation of the ANSYS Fluent model with experiment, (ii) the exploration of design variables using Design of Experiment (Sparse Grid Initialization), (iii) the implementation of response surface method (Genetic Aggregation) to know about dimensional sensitivity among independent and dependent variables and (iv) the application of multiobjective optimization method i.e. NSGA II to optimize the drag and lift coefficient. To identify the superiority, a comparative study between the original and optimized fuselage is presented considering many parameters like pressure contours, velocity contours, pressure coefficients, and streamlines representations. It is evident from various results that the 2D optimum shape significantly minimizes the drag coefficient and increases the lift coefficient. This work also makes room for 3D shape optimization, which helps in prototype fabrication for real-time flight conditions.
基于非支配排序遗传算法的生物启发式无人飞行器圆柱形机身二维数值优化-II
为实现生物启发无人飞行器(UAV)机身的高效气动设计,开发一种系统化方法是当务之急。本研究针对低雷诺数(2e05)飞行条件下可折叠拍翼无人机的二维机身形状参数化进行了多目标优化研究。这项研究工作的新颖之处在于结合 S1223 机翼的特性来预测机身的有效形状设计。本文包括四个部分:(i) ANSYS Fluent 模型与实验的验证;(ii) 利用实验设计(稀疏网格初始化)探索设计变量;(iii) 实施响应面方法(遗传聚合)了解自变量和因变量之间的尺寸敏感性;(iv) 应用多目标优化方法(即 NSGA II)优化阻力和升力系数。为了确定优劣,对原始机身和优化机身进行了比较研究,考虑了许多参数,如压力等值线、速度等值线、压力系数和流线表示法。从各种结果中可以看出,二维最佳形状大大降低了阻力系数,提高了升力系数。这项工作还为三维形状优化提供了空间,有助于在实时飞行条件下制作原型机。
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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