Isogeometric shape optimization of missing rib auxetics with prescribed negative Poisson’s ratio over large strains using genetic algorithm

• Published in: International journal of mechanical sciences Vol. 193; p. 106169
• Main Authors: Pokkalla, Deepak Kumar, Poh, Leong Hien, Quek, Ser Tong
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.03.2021
• Subjects: 3D Printing; Auxetic; Genetic algorithm; Isogeometric analysis; Negative Poisson’s ratio; Optical deformation measurement; Shape optimization; Isogeometric analysis; Optical deformation measurement; 3D Printing; Genetic algorithm; Shape optimization; Negative Poisson’s ratio; Auxetic
• ISSN: 0020-7403; 1879-2162
• DOI: 10.1016/j.ijmecsci.2020.106169

•Isogeometric shape optimization using genetic algorithm for missing rib structures with targeted deformation.•Constant negative Poisson’s ratio achieved for up till 50% effective tensile strain in plane stress with experimental validation.•Prescribed negative Poisson’s ratio achieved for large compressive strain emphasizing challenges in optimization and experiments under compression. •caption: Design of missing rib auxetics with four ligaments using isogeometric genetic algorithm for prescribed constant Poisson’s ratio over large tensile and compressive strains. [Display omitted] This paper presents an isogeometric shape optimization framework using genetic algorithm to design 2D auxetic structures with prescribed Poisson’s ratio over large tensile or compressive strains in the nonlinear deformation regime. The design domain is parametrized using NURBS to allow smoother shape variation of the structure and enable accurate fabrication of the optimized structures. The versatility of the framework is illustrated through the optimization of a missing rib structure with four ligaments under different loading conditions. The manufacturability of specimens using the NURBS and PolyJet 3D printing technology is also shown. The first example focuses on achieving constant negative Poisson’s ratio up to -0.7 within the applied tensile strain of 50% under plane stress condition. As auxetics experiments under large compressive strain are rarely performed and published, the second example demonstrates the optimization for compressive loading. The Poisson’s ratio determined from experiments matches well with the numerical results. The experiments highlight that for very flexible materials, deformation under self-weight and contacts between adjacent unit cells are significant factors in compression, and further investigations are needed.