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Bibliographic Details
Main Authors: Nain, Rishabh, Marzin, Tom, Ramananarivo, Sophie
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.02567
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author Nain, Rishabh
Marzin, Tom
Ramananarivo, Sophie
author_facet Nain, Rishabh
Marzin, Tom
Ramananarivo, Sophie
contents We leverage the snap-through response of a bistable origami mechanism to induce a discontinuous evolution of drag with flow speed. The transition between equilibrium states is passively actuated by airflow, and we demonstrate that large shape reconfiguration over a small increment of flow velocity leads to a pronounced and sudden drop in drag. Moreover, we show that systematically varying the geometrical and mechanical properties of the origami unit enables the tuning of this drag discontinuity and the critical speed and loading at which it occurs. Experimental results are supported by a theoretical aero-elastic model, which further guides inverse design to identify the combination of structural origami parameters for targeted drag collapse. This approach sheds light on harnessing origami-inspired mechanisms for efficient passive drag control in a fluid environment, applicable for load alleviation or situations requiring swift transitions in aerodynamic performances.
format Preprint
id arxiv_https___arxiv_org_abs_2406_02567
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Tunable drag drop via flow-induced snap-through in origami
Nain, Rishabh
Marzin, Tom
Ramananarivo, Sophie
Fluid Dynamics
We leverage the snap-through response of a bistable origami mechanism to induce a discontinuous evolution of drag with flow speed. The transition between equilibrium states is passively actuated by airflow, and we demonstrate that large shape reconfiguration over a small increment of flow velocity leads to a pronounced and sudden drop in drag. Moreover, we show that systematically varying the geometrical and mechanical properties of the origami unit enables the tuning of this drag discontinuity and the critical speed and loading at which it occurs. Experimental results are supported by a theoretical aero-elastic model, which further guides inverse design to identify the combination of structural origami parameters for targeted drag collapse. This approach sheds light on harnessing origami-inspired mechanisms for efficient passive drag control in a fluid environment, applicable for load alleviation or situations requiring swift transitions in aerodynamic performances.
title Tunable drag drop via flow-induced snap-through in origami
topic Fluid Dynamics
url https://arxiv.org/abs/2406.02567