A moving bounds strategy for the parameterization of geometric design variables in the simultaneous shape optimization of curved shell structures and openings

Dan Wang; Weihong Zhang; Jihong Zhu

doi:10.1016/j.finel.2016.07.002

A moving bounds strategy for the parameterization of geometric design variables in the simultaneous shape optimization of curved shell structures and openings

Dan Wang, Weihong Zhang, Jihong Zhu

School of Mechanical Engineering

Northwestern Polytechnical University Xian

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

10 Scopus citations

Abstract

A moving bounds strategy is proposed to implement simultaneous shape optimization of curved shell structures and openings. Design variables related to the hole shape are constrained in a planar reference domain by the moving bounds whose values are adaptively updated as functions of design variables related to the surface by an arc-length rule. It is shown that this strategy is essential not only to ensure the geometric consistence in the simultaneous design process but also to hold the shape-preserving of the mapped FE mesh from reference domains. Numerical results are presented to validate the proposed method.

Original language	English
Pages (from-to)	80-91
Number of pages	12
Journal	Finite Elements in Analysis and Design
Volume	120
DOIs	https://doi.org/10.1016/j.finel.2016.07.002
State	Published - 1 Nov 2016

Keywords

Arc-length rule
Mesh mapping
Moving bounds strategy
Shape optimization
Shape preserving

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10.1016/j.finel.2016.07.002

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title = "A moving bounds strategy for the parameterization of geometric design variables in the simultaneous shape optimization of curved shell structures and openings",

abstract = "A moving bounds strategy is proposed to implement simultaneous shape optimization of curved shell structures and openings. Design variables related to the hole shape are constrained in a planar reference domain by the moving bounds whose values are adaptively updated as functions of design variables related to the surface by an arc-length rule. It is shown that this strategy is essential not only to ensure the geometric consistence in the simultaneous design process but also to hold the shape-preserving of the mapped FE mesh from reference domains. Numerical results are presented to validate the proposed method.",

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N2 - A moving bounds strategy is proposed to implement simultaneous shape optimization of curved shell structures and openings. Design variables related to the hole shape are constrained in a planar reference domain by the moving bounds whose values are adaptively updated as functions of design variables related to the surface by an arc-length rule. It is shown that this strategy is essential not only to ensure the geometric consistence in the simultaneous design process but also to hold the shape-preserving of the mapped FE mesh from reference domains. Numerical results are presented to validate the proposed method.

AB - A moving bounds strategy is proposed to implement simultaneous shape optimization of curved shell structures and openings. Design variables related to the hole shape are constrained in a planar reference domain by the moving bounds whose values are adaptively updated as functions of design variables related to the surface by an arc-length rule. It is shown that this strategy is essential not only to ensure the geometric consistence in the simultaneous design process but also to hold the shape-preserving of the mapped FE mesh from reference domains. Numerical results are presented to validate the proposed method.

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KW - Mesh mapping

KW - Moving bounds strategy

KW - Shape optimization

KW - Shape preserving

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JO - Finite Elements in Analysis and Design

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ER -

A moving bounds strategy for the parameterization of geometric design variables in the simultaneous shape optimization of curved shell structures and openings

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Keywords

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