Shape optimization of buckling-based deployable stiff structures

Ho Min  Lee; Gil Ho Yoon; Jonas Engqvist; Matti Ristinmaa; Mathias Wallin

doi:10.1016/j.mechmachtheory.2024.105605

Shape optimization of buckling-based deployable stiff structures

Ho Min Lee, Gil Ho Yoon, Jonas Engqvist, Matti Ristinmaa, Mathias Wallin

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

Abstract

This study considers deployable structures and presents a novel optimization method that aims to improve the stiffness at the fully deployed state. The considered structures consist of curved beams that deploy through buckling when rotated. The optimization aims to maximize the structural tangent stiffness by modifying the shape of the beam elements. To accurately predict the deformation, Finite Element Method (FEM) simulations were conducted. A design with an increase of up to 19.6% in structural tangent stiffness was achieved, while conserving the structural volume. The approach is validated by manufacturing the deployable structures using laser cutting and performing compression tests. Experimental results show consistency within a 5% range with the optimization results. These findings support the implementation of the optimization scheme for achieving optimum structural designs of deployable structures.

Original language	English
Article number	105605
Journal	Mechanism and Machine Theory
Volume	195
DOIs	https://doi.org/10.1016/j.mechmachtheory.2024.105605
Publication status	Published - 2024 May

Subject classification (UKÄ)

Applied Mechanics

Free keywords

Buckling-induced deployment
Deployable structure
Shape optimization
Tangent stiffness

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10.1016/j.mechmachtheory.2024.105605Licence: CC BY

Solid Mechanics Lab @ LTH
Engqvist, J. (Manager)
Solid Mechanics
Infrastructure

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title = "Shape optimization of buckling-based deployable stiff structures",

abstract = "This study considers deployable structures and presents a novel optimization method that aims to improve the stiffness at the fully deployed state. The considered structures consist of curved beams that deploy through buckling when rotated. The optimization aims to maximize the structural tangent stiffness by modifying the shape of the beam elements. To accurately predict the deformation, Finite Element Method (FEM) simulations were conducted. A design with an increase of up to 19.6% in structural tangent stiffness was achieved, while conserving the structural volume. The approach is validated by manufacturing the deployable structures using laser cutting and performing compression tests. Experimental results show consistency within a 5% range with the optimization results. These findings support the implementation of the optimization scheme for achieving optimum structural designs of deployable structures.",

keywords = "Buckling-induced deployment, Deployable structure, Shape optimization, Tangent stiffness",

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language = "English",

volume = "195",

journal = "Mechanism and Machine Theory",

issn = "0094-114X",

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AU - Lee, Ho Min

AU - Yoon, Gil Ho

AU - Engqvist, Jonas

AU - Ristinmaa, Matti

AU - Wallin, Mathias

PY - 2024/5

Y1 - 2024/5

N2 - This study considers deployable structures and presents a novel optimization method that aims to improve the stiffness at the fully deployed state. The considered structures consist of curved beams that deploy through buckling when rotated. The optimization aims to maximize the structural tangent stiffness by modifying the shape of the beam elements. To accurately predict the deformation, Finite Element Method (FEM) simulations were conducted. A design with an increase of up to 19.6% in structural tangent stiffness was achieved, while conserving the structural volume. The approach is validated by manufacturing the deployable structures using laser cutting and performing compression tests. Experimental results show consistency within a 5% range with the optimization results. These findings support the implementation of the optimization scheme for achieving optimum structural designs of deployable structures.

AB - This study considers deployable structures and presents a novel optimization method that aims to improve the stiffness at the fully deployed state. The considered structures consist of curved beams that deploy through buckling when rotated. The optimization aims to maximize the structural tangent stiffness by modifying the shape of the beam elements. To accurately predict the deformation, Finite Element Method (FEM) simulations were conducted. A design with an increase of up to 19.6% in structural tangent stiffness was achieved, while conserving the structural volume. The approach is validated by manufacturing the deployable structures using laser cutting and performing compression tests. Experimental results show consistency within a 5% range with the optimization results. These findings support the implementation of the optimization scheme for achieving optimum structural designs of deployable structures.

KW - Buckling-induced deployment

KW - Deployable structure

KW - Shape optimization

KW - Tangent stiffness

U2 - 10.1016/j.mechmachtheory.2024.105605

DO - 10.1016/j.mechmachtheory.2024.105605

M3 - Article

AN - SCOPUS:85184668642

SN - 0094-114X

VL - 195

JO - Mechanism and Machine Theory

JF - Mechanism and Machine Theory

M1 - 105605

ER -

Shape optimization of buckling-based deployable stiff structures

Abstract

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