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

Shen, Jiajia; Garrad, Martin; Zhang, Qicheng; Wong, Vico Chun Hei; Pirrera, Alberto; Groh, Rainer M J

Shen, Jiajia; Garrad, Martin; Zhang, Qicheng; Wong, Vico Chun Hei; Pirrera, Alberto; Groh, Rainer M J.

Afiliación

Shen J; Bristol Composites Institute (BCI), School of Civil, Aerospace and Design Engineering, University of Bristol , Bristol BS8 1TR, UK.
Garrad M; Exeter Technologies Group (ETG), Department of Engineering, University of Exeter , Exeter EX4 4PY, UK.
Zhang Q; Department of Engineering Mathematics, University of Bristol , Bristol BS8 1TR, UK.
Wong VCH; SoftLab, Bristol Robotics Laboratory, University of Bristol and University of the West of England , Bristol BS8 1TR, UK.
Pirrera A; Faculty of Science and Engineering, Swansea University , Swansea SA1 8EN, UK.
Groh RMJ; Bristol Composites Institute (BCI), School of Civil, Aerospace and Design Engineering, University of Bristol , Bristol BS8 1TR, UK.

J R Soc Interface ; 21(218): 20240148, 2024 Sep.

Article en En | MEDLINE | ID: mdl-39226926

ABSTRACT

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.

Asunto(s)

Pico; Aves; Animales; Pico/fisiología; Pico/anatomía & histología; Aves/fisiología; Robótica; Modelos Biológicos; Fenómenos Biomecánicos

Palabras clave

elastic tailoring; energy amplification; functional morphology; programmability; snap-through instability; well-behaved nonlinear structures

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Texto completo: 1 Colección: 01-internacional Base de datos: MEDLINE Asunto principal: Pico / Aves Límite: Animals Idioma: En Revista: J R Soc Interface Año: 2024 Tipo del documento: Article País de afiliación: Reino Unido Pais de publicación: Reino Unido

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