Biomimetic composite meta-stabilisers with programmable multi-directional quasi-zero stiffness and vibration isolation

Ravanbod, S; Rahmani, K; Branfoot, C; Karmel, S; Haque, A; Lidgett, M; Shahidi, AM; Alderson, A; Bodaghi, M

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Biomimetic composite meta-stabilisers with programmable multi-directional quasi-zero stiffness and vibration isolation

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Ravanbod, S ORCID: https://orcid.org/0000-0002-6944-5847, Rahmani, K ORCID: https://orcid.org/0000-0002-0815-1562, Branfoot, C, Karmel, S, Haque, A, Lidgett, M, Shahidi, AM, Alderson, A and Bodaghi, M ORCID: https://orcid.org/0000-0002-0707-944X, 2025. Biomimetic composite meta-stabilisers with programmable multi-directional quasi-zero stiffness and vibration isolation. Materials Today Advances, 28: 100661. ISSN 2590-0498

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Official URL: https://doi.org/10.1016/j.mtadv.2025.100661

Abstract

This study introduces the first multidirectional quasi-zero-stiffness (QZS) meta-stabilisers that integrate bio-inspired curvilinear architectures with a sustainable polymer composite developed in this work. The QZS behaviour emerges synergistically from both structural design and nonlinear visco-hyper-elasticity of the newly developed bio-composite. Inspired by the woodpecker's tongue mechanism, the design leverages the interaction of geometry and material features to achieve exceptional damping and vibration isolation performance. The meta-stabilisers employ a Thermoplastic Polyurethane (TPU)/Polyhydroxyalkanoate (PHA) matrix reinforced with 2.5 wt% eggshell powder. It provides a bio-composite with 20 % higher tensile strength and 60 % greater energy dissipation than the unreinforced matrix. A hybrid computational framework, combining finite element modelling of nonlinear visco-hyper-elastic materials and AI-driven optimisation, enables precise control of the plateau region and constant-force output. The bio-composite generates a broad, stable plateau within 0.2–0.8 strain, perfectly matching the deformation regime of QZS structures. Experimental and numerical findings confirm stable QZS behaviour in three orthogonal directions, high vibration isolation capacity, repeatable hysteresis loops, and minimal Mullins effect over multiple cycles. In addition, the meta-stabilisers are programmable, where constant-force is tuneable between 0.5 and 220 N and displacement range between 1 and 7 mm. Under both periodic and random excitation, the meta-stabilisers achieved up to 100 % suppression of periodic vibrations and 77 % reduction under random vibrational off-road conditions. These results establish a new class of bio-inspired, sustainable, and programmable vibration control systems, offering a scalable, low-cost alternative to conventional active/passive noise/vibration/harshness solutions.

Item Type:	Journal article
Publication Title:	Materials Today Advances
Creators:	Ravanbod, S., Rahmani, K., Branfoot, C., Karmel, S., Haque, A., Lidgett, M., Shahidi, A.M., Alderson, A. and Bodaghi, M.
Publisher:	Elsevier
Date:	December 2025
Volume:	28
ISSN:	2590-0498
Identifiers:	Number Type 10.1016/j.mtadv.2025.100661 DOI S2590049825001067 Publisher Item Identifier 2532200 Other
Rights:	© 2025 the authors. Published by Elsevier Ltd. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/)
Divisions:	Schools > School of Science and Technology
Record created by:	Jonathan Gallacher
Date Added:	25 Nov 2025 09:33
Last Modified:	25 Nov 2025 09:33
URI:	https://irep.ntu.ac.uk/id/eprint/54795