Jenmy Zimi Zhang scite author profile

This paper presents a computationally tractable approach for designing lattice structures for stiffness and strength. Yielding in the mesostructure is determined by a worst-case stress analysis of the homogenization simulation data. This provides a physically meaningful, generalizable, and conservative way to estimate structural failure in three-dimensional functionally graded lattice structures composed of any unit cell architectures. Computational efficiency of the design framework is ensured by developing surrogate models for the unit cell stiffness and strength as a function of density. The surrogate models are then used in the coarse-scale analysis and synthesis. The proposed methodology further uses a compact representation of the material distribution via B-splines, which reduces the size of the design parameter space while ensuring a smooth density variation that is desirable for manufacturing. The proposed method is demonstrated in compliance minimization studies using two types of unit cells with distinct mechanical properties. The effects of B-spline mesh refinement and the presence of a stress constraint on the optimization results are also investigated.

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Efficient Monolithic Solution Algorithm for High-Fidelity Aerostructural Analysis and Optimization

Zhang

Zingg

2018

AIAA Journal

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Stress-Constrained Design of Functionally Graded Lattice Structures With Spline-Based Dimensionality Reduction

Zhang

Sharpe

Seepersad

2020

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This paper presents a computationally tractable approach for designing lattice structures for stiffness and strength. Yielding in the mesostructure is determined by a worst-case stress analysis of the homogenization simulation data. This provides a physically meaningful, generalizable, and conservative way to estimate structural failure in three-dimensional functionally graded lattice structures composed of any unit cell architectures. Computational efficiency of the design framework is ensured by developing surrogate models for the unit cell stiffness and strength as a function of density. The surrogate models are then used in the coarse-scale analysis and synthesis. The proposed methodology further uses a compact representation of the material distribution via B-splines, which reduces the size of the design parameter space while ensuring a smooth density variation that is desirable for manufacturing. The proposed method is demonstrated in compliance with minimization studies using two types of unit cells with distinct mechanical properties. The effects of B-spline mesh refinement and the presence of a stress constraint on the optimization results are also investigated.

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High-Fidelity Aerostructural Optimization with Integrated Geometry Parameterization and Mesh Movement

Zhang

Khosravi

Zingg

2015

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Jenmy Zimi Zhang

High-fidelity aerostructural optimization with integrated geometry parameterization and mesh movement

Stress-Constrained Design of Functionally Graded Lattice Structures With Spline-Based Dimensionality Reduction

Efficient Monolithic Solution Algorithm for High-Fidelity Aerostructural Analysis and Optimization

Stress-Constrained Design of Functionally Graded Lattice Structures With Spline-Based Dimensionality Reduction

High-Fidelity Aerostructural Optimization with Integrated Geometry Parameterization and Mesh Movement

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