Abstract
A fast shape optimization strategy for free form shell structure design with structural dynamics criteria is proposed in this paper. The structures are modelled with Non-Uniform Rational B-Spline based isogeometric Kirchhoff-Love shell elements. The substitution of the traditional finite elements not only makes the mesh model geometrically exact but also avoids the laborious mesh regeneration during the design update. As for the structural response evaluation, the modal synthesis method is adopted to avoid a repeated evaluation of some substructures where there are no designed variables attached; thus, the model reanalysis is speeded up. A bottom-up strategy for the analytical design sensitivity evaluation is also proposed here; the element-level analytical sensitivity with respect to the inherent shape parameters is firstly calculated from which the design sensitivity is then extracted with the help of a sensitivity map. Finally, gradient based algorithm is used to solve the optimization problem. Several examples show that our approach is flexible and efficient for fast free form shell structure optimization.
Highlights
Isogeometric analysis (IGA) [1] is a promising method which can bridge the gap between computer aided design (CAD) and computer aided analysis (CAE)
The structure is modelled with IGA Kirchhoff-Love shell elements
A framework for shell shape optimization considering structural dynamic criteria is proposed. It is based on the IGA Kirchhoff-Love shell element
Summary
Isogeometric analysis (IGA) [1] is a promising method which can bridge the gap between computer aided design (CAD) and computer aided analysis (CAE). It is a special finite element method (FEM) with an exact geometrical mapping. Unlike traditional FEM where the analysis model (meshes) is a faceted approximation of the CAD model, the IGA analysis model is geometrically exact. Wherever the traditional FEM can be used, IGA can be used, e.g., various mechanics problems [1, 3,4,5,6], electromagnetic problems [7, 8], and heat transfer problem [9]. The IGA solutions are more efficient and robust for these problems compared with the traditional FEM solutions [10]
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