Passive wing deployment and retraction in beetles and flapping microrobots

arXiv - PHYS - Biological Physics Pub Date : 2024-07-25 DOI:arxiv-2407.18180

Hoang-Vu Phan, Hoon Cheol Park, Dario Floreano

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Abstract

Birds, bats and many insects can tuck their wings against their bodies at rest and deploy them to power flight. Whereas birds and bats use well-developed pectoral and wing muscles and tendons, how insects control these movements remains unclear, as mechanisms of wing deployment and retraction vary among insect species. Beetles (Coleoptera) display one of the most complex wing mechanisms. For example, in rhinoceros beetles, the wing deployment initiates by fully opening the elytra and partially releasing the hindwings from the abdomen. Subsequently, the beetle starts flapping, elevates the hindwings at the bases, and unfolds the wingtips in an origami-like fashion. Whilst the origami-like fold have been extensively explored, limited attention has been given to the hindwing base deployment and retraction, which are believed to be driven by thoracic muscles. Using high-speed cameras and robotic flapping-wing models, here we demonstrate that rhinoceros beetles can effortlessly elevate the hindwings to flight position without the need for muscular activity. We show that opening the elytra triggers a spring-like partial release of the hindwings from the body, allowing the clearance needed for subsequent flapping motion that brings the hindwings into flight position. The results also show that after flight, beetles can leverage the elytra to push the hindwings back into the resting position, further strengthening the hypothesis of a passive deployment mechanism. Finally, we validate the hypothesis with a flapping microrobot that passively deploys its wings for stable controlled flight and retracts them neatly upon landing, which offers a simple yet effective approach to the design of insect-like flying micromachines.

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甲虫和拍打式微型机器人的被动展翅和缩翅

鸟类、蝙蝠和许多昆虫都能在静止时将翅膀紧贴身体，并展开翅膀为飞行提供动力。鸟类和蝙蝠使用发达的胸肌、翼肌和肌腱，而昆虫如何控制这些动作尚不清楚，因为不同种类昆虫的翅膀展开和收回机制各不相同。甲虫（鞘翅目）的翅膀机制最为复杂。例如，在犀甲虫中，翅膀展开是通过完全张开前翅并从腹部释放部分后翅开始的。随后，甲虫开始拍打，抬高后翅基部，并以类似折纸的方式展开翼尖。虽然对折纸状折叠进行了广泛的研究，但对后翅基部展开和缩回的研究却很有限，因为后翅基部展开和缩回被认为是由胸肌驱动的。利用高速摄像机和机器人拍翼模型，我们在这里证明犀角金龟子可以毫不费力地将后翅升至飞行位置，而无需肌肉活动。我们发现，打开背甲会引发后翅像弹簧一样从身体上部分释放，从而为随后的拍打运动提供所需的间隙，使后翅进入飞行位置。研究结果还表明，甲虫在飞行后可以利用后翅的后缘将后翅推回静止位置，从而进一步加强了通过部署机制的假说。最后，我们用一个拍打式微型机器人验证了这一假设，它能被动地展开翅膀进行稳定可控的飞行，并在着陆时整齐地收回翅膀，这为设计类似昆虫的飞行微型机械提供了一种简单而有效的方法。

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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arXiv - PHYS - Biological Physics

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