Indentation and stability of woven domes

Samuel Poincloux; Célestin Vallat; Tian Chen; Tomohiko G. Sano; Pedro M. Reis

doi:10.1016/j.eml.2023.101968

Indentation and stability of woven domes

Samuel Poincloux, Célestin Vallat, Tian Chen, Tomohiko G. Sano, Pedro M. Reis

Research output: Contribution to journal › Article › peer-review

Abstract

Discrete domes are doubly curved structures comprising a network of beam-like elements. We study the mechanics of discrete domes made of ribbons woven in a pentagonal triaxial pattern. Experiments and finite element simulations are performed to characterize the mechanical response of each woven dome under indentation. The observed nonlinear response features force maxima, snap-through inversion, and non-monotonic evolution, leading to additional stable configurations. The dome's rest shape can be tuned continuously by designing the in-plane curvature of the ribbons and is then perturbed by adjustable clamped boundary conditions at their extremities. These control parameters are leveraged to smoothly and selectively modify the nonlinear features of the mechanical response, including multi-stability. Finally, we suggest a simplified model based on an elastica approximation to predict the stability of the inverted state successfully. The strong geometrical constraints imposed by the weaving pattern and the ribbons enable us to rationalize and tune the indentation response of these intriguing discrete structures.

Original language	English
Article number	101968
Journal	Extreme Mechanics Letters
Volume	59
DOIs	https://doi.org/10.1016/j.eml.2023.101968
Publication status	Published - 2023 Mar
Externally published	Yes

Keywords

Bistability
Discrete domes
Indentation
Triaxial weaving

ASJC Scopus subject areas

Bioengineering
Chemical Engineering (miscellaneous)
Engineering (miscellaneous)
Mechanics of Materials
Mechanical Engineering

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10.1016/j.eml.2023.101968

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title = "Indentation and stability of woven domes",

abstract = "Discrete domes are doubly curved structures comprising a network of beam-like elements. We study the mechanics of discrete domes made of ribbons woven in a pentagonal triaxial pattern. Experiments and finite element simulations are performed to characterize the mechanical response of each woven dome under indentation. The observed nonlinear response features force maxima, snap-through inversion, and non-monotonic evolution, leading to additional stable configurations. The dome's rest shape can be tuned continuously by designing the in-plane curvature of the ribbons and is then perturbed by adjustable clamped boundary conditions at their extremities. These control parameters are leveraged to smoothly and selectively modify the nonlinear features of the mechanical response, including multi-stability. Finally, we suggest a simplified model based on an elastica approximation to predict the stability of the inverted state successfully. The strong geometrical constraints imposed by the weaving pattern and the ribbons enable us to rationalize and tune the indentation response of these intriguing discrete structures.",

keywords = "Bistability, Discrete domes, Indentation, Triaxial weaving",

author = "Samuel Poincloux and C{\'e}lestin Vallat and Tian Chen and Sano, {Tomohiko G.} and Reis, {Pedro M.}",

note = "Funding Information: The authors thank Guangchao Wan for providing the prediction data of [34] for Fig. 5 . Samuel Poincloux acknowledges the financial support from the Japanese Society for the Promotion of Science as a JSPS International Research Fellow. Publisher Copyright: {\textcopyright} 2023 The Authors",

year = "2023",

month = mar,

doi = "10.1016/j.eml.2023.101968",

language = "English",

volume = "59",

journal = "Extreme Mechanics Letters",

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T1 - Indentation and stability of woven domes

AU - Poincloux, Samuel

AU - Vallat, Célestin

AU - Chen, Tian

AU - Sano, Tomohiko G.

AU - Reis, Pedro M.

N1 - Funding Information: The authors thank Guangchao Wan for providing the prediction data of [34] for Fig. 5 . Samuel Poincloux acknowledges the financial support from the Japanese Society for the Promotion of Science as a JSPS International Research Fellow. Publisher Copyright: © 2023 The Authors

PY - 2023/3

Y1 - 2023/3

N2 - Discrete domes are doubly curved structures comprising a network of beam-like elements. We study the mechanics of discrete domes made of ribbons woven in a pentagonal triaxial pattern. Experiments and finite element simulations are performed to characterize the mechanical response of each woven dome under indentation. The observed nonlinear response features force maxima, snap-through inversion, and non-monotonic evolution, leading to additional stable configurations. The dome's rest shape can be tuned continuously by designing the in-plane curvature of the ribbons and is then perturbed by adjustable clamped boundary conditions at their extremities. These control parameters are leveraged to smoothly and selectively modify the nonlinear features of the mechanical response, including multi-stability. Finally, we suggest a simplified model based on an elastica approximation to predict the stability of the inverted state successfully. The strong geometrical constraints imposed by the weaving pattern and the ribbons enable us to rationalize and tune the indentation response of these intriguing discrete structures.

AB - Discrete domes are doubly curved structures comprising a network of beam-like elements. We study the mechanics of discrete domes made of ribbons woven in a pentagonal triaxial pattern. Experiments and finite element simulations are performed to characterize the mechanical response of each woven dome under indentation. The observed nonlinear response features force maxima, snap-through inversion, and non-monotonic evolution, leading to additional stable configurations. The dome's rest shape can be tuned continuously by designing the in-plane curvature of the ribbons and is then perturbed by adjustable clamped boundary conditions at their extremities. These control parameters are leveraged to smoothly and selectively modify the nonlinear features of the mechanical response, including multi-stability. Finally, we suggest a simplified model based on an elastica approximation to predict the stability of the inverted state successfully. The strong geometrical constraints imposed by the weaving pattern and the ribbons enable us to rationalize and tune the indentation response of these intriguing discrete structures.

KW - Bistability

KW - Discrete domes

KW - Indentation

KW - Triaxial weaving

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Indentation and stability of woven domes

Abstract

Keywords

ASJC Scopus subject areas

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