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Main Authors: Mao, Hanzhang, Chandler, Thomas G. J., Han, Mark, Spagnolie, Saverio E.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.10382
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author Mao, Hanzhang
Chandler, Thomas G. J.
Han, Mark
Spagnolie, Saverio E.
author_facet Mao, Hanzhang
Chandler, Thomas G. J.
Han, Mark
Spagnolie, Saverio E.
contents Bending the edge of a thin elastic material promotes rigidity far from its clamped boundary. However, this curvature-induced rigidity can be overwhelmed by gravity or other external loading, resulting in elastic buckling and large deformations. We consider the role of body geometry on this competition using experiments, numerical simulations, and reduced-order models. Finite element simulations are performed using a model nonlinear hyperelastic material, and a theoretical framework is proposed that incorporates small lateral curvatures, large longitudinal rotations, and a varying cross-sectional width. A particular focus is on the comparison between rectangular and triangular sheets, and trapezoidal sheets in between. Sheet geometry affects downward tip deflection by changing the relative importance of the sheet's weight and the rigidity provided by curvature, often in subtle ways. In extreme cases, non-monotonic deflection is observed with increasing sheet length, and a region of hysteretic bistability emerges, becoming more pronounced with rectangular sheets and large imposed curvatures. These findings demonstrate the profound impact of geometry on the competition between curvature-induced rigidity and gravity-induced deformation in thin elastic materials.
format Preprint
id arxiv_https___arxiv_org_abs_2411_10382
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Geometric dependence of curvature-induced rigidity
Mao, Hanzhang
Chandler, Thomas G. J.
Han, Mark
Spagnolie, Saverio E.
Soft Condensed Matter
Materials Science
Bending the edge of a thin elastic material promotes rigidity far from its clamped boundary. However, this curvature-induced rigidity can be overwhelmed by gravity or other external loading, resulting in elastic buckling and large deformations. We consider the role of body geometry on this competition using experiments, numerical simulations, and reduced-order models. Finite element simulations are performed using a model nonlinear hyperelastic material, and a theoretical framework is proposed that incorporates small lateral curvatures, large longitudinal rotations, and a varying cross-sectional width. A particular focus is on the comparison between rectangular and triangular sheets, and trapezoidal sheets in between. Sheet geometry affects downward tip deflection by changing the relative importance of the sheet's weight and the rigidity provided by curvature, often in subtle ways. In extreme cases, non-monotonic deflection is observed with increasing sheet length, and a region of hysteretic bistability emerges, becoming more pronounced with rectangular sheets and large imposed curvatures. These findings demonstrate the profound impact of geometry on the competition between curvature-induced rigidity and gravity-induced deformation in thin elastic materials.
title Geometric dependence of curvature-induced rigidity
topic Soft Condensed Matter
Materials Science
url https://arxiv.org/abs/2411.10382