Mathematical modelling for compliance-assisted artificial muscle based ornithopter

IF 1.2 4区工程技术 Q3 ENGINEERING, AEROSPACE

Aircraft Engineering and Aerospace Technology Pub Date : 2024-05-17 DOI:10.1108/aeat-07-2023-0180

Syam Narayanan S., Rajalakshmi Pachamuthu, Alex T. Biju, Srilekha Madupu

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引用次数: 0

Abstract

Purpose This study aims to discuss the mathematical modelling of a compliance-assisted flapping mechanism and morphable structures for an UAV. Design/methodology/approach A compliance-assisted flapping wing was designed and modelled mathematically, and signals for the corresponding curves were calculated. The actual wing tip trace of a hummingbird was taken, and variables a, b, h and k were calculated from the image. This data was given to the mathematical model for plotting the graph, and the curve was compared with the input curve. The wing frame and mechanism for control surfaces using morphing is modelled along with single pivoted spine for centre of gravity augmentation and flight orientation control. Findings The model efficiently approximates the 2D path of the wing using line segments using the muscle and compliance mechanism. Practical implications Using a compliance-assisted flapping mechanism offers practical advantages. It allows us to synchronize the flapping frequency with the input signal frequency, ensuring efficient operation. Additionally, the authors can enhance the torque output by using multiple muscle strands, resulting in a substantial increase in the system’s torque-to-weight ratio. This approach proves to be more favourable when compared to conventional methods involving motors or servos, ultimately offering a more efficient and robust solution for practical application. Social implications This model focuses on creating a flexible and tunable mechanism that can at least trace four types of wing traces from the same design, for shifting from one mode of flight to another. Originality/value Conventional ornithopter flapping mechanisms are gear or servo driven and cannot trace a wing tip, but some can trace complicated curves, but only one at a time. This model can trace multiple curves using the same hardware, allowing the user to program the curve based on their needs or bird. The authors may vary the shape of the wing tip trace to switch between forward flight, hovering, backward flying, etc., which is not conceivable with any traditional flapping mechanism.

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基于顺应性辅助人工肌肉的鸟类直升机数学建模

目的本研究旨在讨论无人飞行器的顺应性辅助拍翼机构和可变形结构的数学建模。实际拍摄了蜂鸟的翼尖轨迹，并根据图像计算出变量 a、b、h 和 k。将这些数据交给数学模型绘制曲线图，并将曲线与输入曲线进行比较。研究结果该模型利用肌肉和顺应性机制，通过线段有效地逼近了机翼的二维路径。它允许我们将拍打频率与输入信号频率同步，确保高效运行。此外，作者还可以通过使用多股肌肉来增强扭矩输出，从而大幅提高系统的扭矩重量比。这种方法与涉及电机或伺服系统的传统方法相比更为有利，最终为实际应用提供了一种更高效、更稳健的解决方案。社会意义该模型的重点是创建一种灵活、可调的机构，该机构至少可以从同一设计中追踪四种类型的翼迹，以便从一种飞行模式转换到另一种飞行模式。该模型可以使用相同的硬件追踪多条曲线，用户可以根据自己的需要或鸟类的情况对曲线进行编程。作者可以改变翼尖轨迹的形状，在向前飞行、悬停、向后飞行等之间切换，这是任何传统拍打机构都无法想象的。

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

Aircraft Engineering and Aerospace Technology 工程技术-工程：宇航

CiteScore

3.20

自引率

13.30%

发文量

168

审稿时长

8 months

期刊介绍： Aircraft Engineering and Aerospace Technology provides a broad coverage of the materials and techniques employed in the aircraft and aerospace industry. Its international perspectives allow readers to keep up to date with current thinking and developments in critical areas such as coping with increasingly overcrowded airways, the development of new materials, recent breakthroughs in navigation technology - and more.