Numerical simulation framework of bird-inspired ornithopter in forward flight

IF 3.4 2区工程技术 Q1 ENGINEERING, MECHANICAL

Journal of Fluids and Structures Pub Date : 2025-01-07 DOI:10.1016/j.jfluidstructs.2024.104263

Hyeon-Ho Yang, Sang-Gil Lee, Eun-Hyuck Lee, Jae-Hung Han

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引用次数: 0

Abstract

This study presents an efficient numerical simulation framework for analyzing the flight dynamics of bird-inspired ornithopters in forward flight. The framework integrates a modified Unsteady Vortex Lattice Method (UVLM) with a Multi-Flexible-Body Dynamics (MFBD) model to simulate the Fluid-Structure Interaction (FSI) that occurs during the flapping flight. The UVLM is enhanced with a Pseudo-Leading-Edge Vortex (PLEV) model and an Adaptive Wake-Shedding (AWS) scheme to address limitations related to the leading edge vortex and spanwise wake-shedding. Additionally, the structural model of the ornithopter's flexible main wing is modeled using a modal-based reduced-order model generated through component mode synthesis. The framework is validated through wind tunnel tests on rigid and flexible wing models, demonstrating errors of <10 % in predicting mean lift and thrust forces. The ORNithopter Integrated Simulation Program (ORNISP), developed as a MATLAB App, is utilized to perform a flight dynamic simulation under free-flight conditions. The trim conditions for a forward flight of an ornithopter prototype named KRoFalcon (KAIST Robotic Falcon) are estimated. The simulation results show errors within 7 % for flight speed and angle of attack compared to flight test data. Additionally, the simulation results under free-flight and restricted degrees of freedom conditions are compared, and it shows that the flight simulation with restricted heaving and pitching can overestimate the aerodynamic forces. The proposed FSI simulation framework shows more efficient computational time than the FSI simulation using computational fluid dynamics and structural dynamics solvers, ensuring sufficient fidelity in aerodynamic force estimation.

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仿鸟扑翼机向前飞行的数值模拟框架

本研究提出了一种有效的数值模拟框架，用于分析鸟型扑翼机在前向飞行中的飞行动力学。该框架将改进的非定常涡点阵法（UVLM）与多柔体动力学（MFBD）模型相结合，用于模拟扑翼飞行过程中的流固耦合（FSI）。UVLM采用伪前缘涡（PLEV）模型和自适应尾迹脱落（AWS）方案进行增强，以解决与前缘涡和展向尾迹脱落相关的限制。此外，采用构件模态综合生成的基于模态的降阶模型建立了扑翼机柔性主翼的结构模型。通过对刚性和柔性机翼模型进行风洞试验，验证了该框架在预测平均升力和推力方面的误差为10%。ornithoter集成仿真程序（ORNISP）作为MATLAB应用程序开发，用于在自由飞行条件下进行飞行动态仿真。对韩国科学技术院（KAIST）机器人猎鹰（KRoFalcon）的扑翼机原型机进行前飞时的内饰条件进行了估计。仿真结果表明，与试飞数据相比，飞行速度和迎角误差在7%以内。另外，对比了自由飞行和限制自由度条件下的仿真结果，发现限制升沉和俯仰条件下的飞行仿真会高估气动力。所提出的FSI仿真框架比使用计算流体动力学和结构动力学求解器的FSI仿真计算时间更短，保证了气动力估计的保真度。

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

Journal of Fluids and Structures 工程技术-工程：机械

CiteScore

6.90

自引率

8.30%

发文量

173

审稿时长

65 days

期刊介绍： The Journal of Fluids and Structures serves as a focal point and a forum for the exchange of ideas, for the many kinds of specialists and practitioners concerned with fluid–structure interactions and the dynamics of systems related thereto, in any field. One of its aims is to foster the cross–fertilization of ideas, methods and techniques in the various disciplines involved. The journal publishes papers that present original and significant contributions on all aspects of the mechanical interactions between fluids and solids, regardless of scale.