A rapid-response soft end effector inspired by the hummingbird beak.

IF 3.7 2区 综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES Journal of The Royal Society Interface Pub Date : 2024-09-01 Epub Date: 2024-09-04 DOI:10.1098/rsif.2024.0148
Jiajia Shen, Martin Garrad, Qicheng Zhang, Vico Chun Hei Wong, Alberto Pirrera, Rainer M J Groh
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Abstract

Biology is a wellspring of inspiration in engineering design. This paper delves into the application of elastic instabilities-commonly used in biological systems to facilitate swift movement-as a power-amplification mechanism for soft robots. Specifically, inspired by the nonlinear mechanics of the hummingbird beak-and shedding further light on it-we design, build and test a novel, rapid-response, soft end effector. The hummingbird beak embodies the capacity for swift movement, achieving closure in less than [Formula: see text]. Previous work demonstrated that rapid movement is achieved through snap-through deformations, induced by muscular actuation of the beak's root. Using nonlinear finite element simulations coupled with continuation algorithms, we unveil a representative portion of the equilibrium manifold of the beak-inspired structure. The exploration involves the application of a sequence of rotations as exerted by the hummingbird muscles. Specific emphasis is placed on pinpointing and tailoring the position along the manifold of the saddle-node bifurcation at which the onset of elastic instability triggers dynamic snap-through. We show the critical importance of the intermediate rotation input in the sequence, as it results in the accumulation of elastic energy that is then explosively released as kinetic energy upon snap-through. Informed by our numerical studies, we conduct experimental testing on a prototype end effector fabricated using a compliant material (thermoplastic polyurethane). The experimental results support the trends observed in the numerical simulations and demonstrate the effectiveness of the bio-inspired design. Specifically, we measure the energy transferred by the soft end effector to a pendulum, varying the input levels in the sequence of prescribed rotations. Additionally, we demonstrate a potential robotic application in scenarios demanding explosive action. From a mechanics perspective, our work sheds light on how pre-stress fields can enable swift movement in soft robotic systems with the potential to facilitate high input-to-output energy efficiency.

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从蜂鸟喙中汲取灵感的快速反应软末端效应器。
生物学是工程设计灵感的源泉。本文深入探讨了弹性不稳定性的应用--生物系统中常用弹性不稳定性来促进快速运动--作为软机器人的动力增强机制。具体来说,受蜂鸟喙非线性力学的启发,我们设计、制造并测试了一种新型快速反应软末端效应器。蜂鸟喙体现了快速运动的能力,可在不到[公式:见正文]的时间内实现闭合。之前的研究表明,快速移动是通过喙根部的肌肉驱动引起的扣穿变形实现的。利用非线性有限元模拟和延续算法,我们揭示了喙启发结构平衡流形的代表性部分。探索涉及蜂鸟肌肉施加的一连串旋转。重点是沿着鞍节点分叉的流形精确定位和调整位置,在这个位置上,弹性不稳定性的开始会触发动态速穿。我们展示了中间旋转输入在这一序列中的关键重要性,因为它导致弹性能量的积累,然后在快速通过时作为动能爆炸性地释放出来。在数值研究的基础上,我们对使用顺应性材料(热塑性聚氨酯)制造的末端效应器原型进行了实验测试。实验结果支持数值模拟中观察到的趋势,并证明了生物启发设计的有效性。具体来说,我们测量了软末端效应器传递给摆锤的能量,在规定的旋转序列中改变输入水平。此外,我们还展示了机器人在需要爆炸性动作的场景中的潜在应用。从力学角度来看,我们的工作揭示了预应力场如何在软机器人系统中实现快速运动,并有可能促进高输入输出能效。
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来源期刊
Journal of The Royal Society Interface
Journal of The Royal Society Interface 综合性期刊-综合性期刊
CiteScore
7.10
自引率
2.60%
发文量
234
审稿时长
2.5 months
期刊介绍: J. R. Soc. Interface welcomes articles of high quality research at the interface of the physical and life sciences. It provides a high-quality forum to publish rapidly and interact across this boundary in two main ways: J. R. Soc. Interface publishes research applying chemistry, engineering, materials science, mathematics and physics to the biological and medical sciences; it also highlights discoveries in the life sciences of relevance to the physical sciences. Both sides of the interface are considered equally and it is one of the only journals to cover this exciting new territory. J. R. Soc. Interface welcomes contributions on a diverse range of topics, including but not limited to; biocomplexity, bioengineering, bioinformatics, biomaterials, biomechanics, bionanoscience, biophysics, chemical biology, computer science (as applied to the life sciences), medical physics, synthetic biology, systems biology, theoretical biology and tissue engineering.
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