Stiffener layout optimization of thin walled structures

Weihong Zhang; Shengdong Zhang; Tong Gao

Stiffener layout optimization of thin walled structures

Weihong Zhang, Shengdong Zhang, Tong Gao

School of Mechanical Engineering

Northwestern Polytechnical University Xian

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

22 Scopus citations

Abstract

The stiffener layout optimization of thin walled structures is addressed in this article using a topology optimization method. Taking into consideration the complexities and wide applications of thin walled stiffened structures in aeronautic and astronautic fields, the article proposes a new geometric background grid (GBG) method suitable for stiffener design with unstructured finite element meshes. On the one hand, the stiffener definition is parameterized by this method using the background grid size. On the other hand, the definition of the background grid in the curve-lined coordinate system makes it possible to perform stiffener design of 3D curved shells. To validate the GBG method, it is applied to the stiffness maximization of plane and curved panels. Numerical examples show that this method can provide satisfactory results for stiffener layout.

Original language	English
Pages (from-to)	2126-2131
Number of pages	6
Journal	Hangkong Xuebao/Acta Aeronautica et Astronautica Sinica
Volume	30
Issue number	11
State	Published - Nov 2009

Keywords

Geometric background grid (GBG)
Layout optimization
Stiffener design
Stiffness maximization
Thin walled structures
Topology optimization

Cite this

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AB - The stiffener layout optimization of thin walled structures is addressed in this article using a topology optimization method. Taking into consideration the complexities and wide applications of thin walled stiffened structures in aeronautic and astronautic fields, the article proposes a new geometric background grid (GBG) method suitable for stiffener design with unstructured finite element meshes. On the one hand, the stiffener definition is parameterized by this method using the background grid size. On the other hand, the definition of the background grid in the curve-lined coordinate system makes it possible to perform stiffener design of 3D curved shells. To validate the GBG method, it is applied to the stiffness maximization of plane and curved panels. Numerical examples show that this method can provide satisfactory results for stiffener layout.

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Stiffener layout optimization of thin walled structures

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Keywords

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