Bioinspired flapping wing UAV and its kinematic analysis—a novel approach

IF 1.9 4区 工程技术 Q3 ENGINEERING, MECHANICAL
Bhushan Dewangan, Debendra Pradhan, H. Roy
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引用次数: 1

Abstract

A rich development in the domain of flapping wing Unmanned Aerial Vehicle (FWUAV) is not yet entirely sufficient to implement the findings of real-life situations. Using the limited knowledge of this domain, this work enlightens the scientific community by introducing a homegrown, patented flapping mechanism of foldable wing aerial vehicle. The synchronized dual wing flapping mechanism consists of a crank slotted lever, a gear train and a special type of 4 bar kinematic chain. The entire sets are powered by a DC motor through crank connected motor shaft. Flapping cycle works on quick return principle generated by crank slotted lever mechanism and foldable wing structure by the special type 4 bar chain with gear train ensure the controlled flapping frequency, twist angle, altitude gain and attitude parameters (Pitch, roll, yaw). This work majorly focuses on the kinematics of the developed bio mimic mechanism by observing the variation of flapping wing orientation, angular velocity and angular acceleration with respect to the crank rotation as well as different crank speeds. These analytically obtained kinematic parameters are further validated after developing a three-dimensional model of the said mechanism as well as multibody analysis by MSC ADAMS. The patterns of the kinematic parameters such that angular displacement, angular velocity and angular acceleration between output and input links are similar and its validation guarantees the correctness of developed mechanism. The kinematic analyzes of linkages are also essential for dynamic study as well as fabrication of prototype.
仿生扑翼无人机及其运动学分析——一种新方法
扑翼无人机(FWUAV)领域的丰富发展尚未完全足以实现现实情况的研究结果。利用该领域有限的知识,本工作通过介绍一种自主研发的专利可折叠翼飞行器的扑动机构,给科学界带来启发。同步双翼扑动机构由曲柄开槽杆、轮系和一种特殊的4杆运动链组成。整套机组由直流电机通过曲柄连接电机轴提供动力。扑翼循环工作原理是由曲柄开槽杠杆机构产生的快速返回原理和特殊的4杆链带齿轮传动的可折叠翼结构,确保控制扑翼频率、扭转角、高度增益和姿态参数(俯仰、滚转、偏航)。本工作主要通过观察扑翼方向、角速度和角加速度随曲柄旋转以及不同曲柄速度的变化,对所开发的生物模拟机构进行运动学研究。通过建立该机构的三维模型以及MSC ADAMS的多体分析,进一步验证了这些解析得到的运动学参数。输出和输入环节的角位移、角速度、角加速度等运动参数的分布规律相似,其验证保证了所研制机构的正确性。连杆机构的运动学分析对于动力学研究和样机制作也是必不可少的。
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
4.10
自引率
11.10%
发文量
38
审稿时长
>12 weeks
期刊介绍: The Journal of Multi-body Dynamics is a multi-disciplinary forum covering all aspects of mechanical design and dynamic analysis of multi-body systems. It is essential reading for academic and industrial research and development departments active in the mechanical design, monitoring and dynamic analysis of multi-body systems.
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