Bioinspired Golden Spiral Shapes on Crushing Protection Behaviors of Tubular Structures

Sherman, John; Zhang, Wen; Waheed, Hamza; Albarran, Alexis; Crumpler, Hunter; Xu, Jun

doi:10.1002/adem.202300349

Adv Eng Mater

2023

DOI: 10.1002/adem.202300349

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Bioinspired Golden Spiral Shapes on Crushing Protection Behaviors of Tubular Structures

John Sherman,

Wen Zhang,

Hamza Waheed

et al.

Abstract: Advanced structure design for energy absorption is a long‐lasting pursuit due to its fascinating scientific merit in mechanics and important engineering application. Curves, a type of mathematical variation in geometry, are widely adopted in the biological system and biomaterial structures after long‐time nature evolution toward optimization and adaption. Inspired by nature, a novel type of tubular structure is designed with golden spiral curvature. With the variations in the hierarchy of the supporting spiral… Show more

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2024

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References 41 publications

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Bioinspired Design of Isotropic Lattices with Tunable and Controllable Anisotropy

Boda,

Panda,

Kumar

2024

Adv Eng Mater

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This study presents novel nested isotropic lattices, drawing inspiration from bio‐architectures found in cortical bone osteons, golden spirals, and fractals. These lattices provide tunable anisotropy by integrating architectural elements like “nesting orders (NOs)” and corresponding “nesting orientations (NORs),” along with repetitive self‐similar X‐cross struts and three fourfold axes of symmetry, resulting in a wide spectrum of novel lattice designs. Nine mon‐onest and 20 multinest lattices, along with 252 parametric variations, are realized. Employing finite element‐based numerical homogenization, elastic stiffness tensors are estimated to evaluate the anisotropic measure—Zener ratio and elastic modulus. The mono‐nest lattices generated considering higher NOs and respective NORs exhibit a transition from shear dominant to tensile‐compression dominant (TCD) anisotropic behavior and their strut size variations show a strong influence on performances. In contrast, multinest lattices exhibit isotropic and neo‐isotropic characteristics, with strut size mismatch exerting more influence on the Zener ratio. Increasing NOs and NORs result in isotropic or TCD behavior for most multinest lattices, with strut size mismatch leading to many isotropic lattices. These bioinspired nested lattices, coupled with advancements in additive manufacturing, hold potential for diverse applications.

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Bioinspired Design of Isotropic Lattices with Tunable and Controllable Anisotropy

Boda,

Panda,

Kumar

2024

Adv Eng Mater

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Bioinspired Golden Spiral Shapes on Crushing Protection Behaviors of Tubular Structures

Cited by 1 publication

References 41 publications

Bioinspired Design of Isotropic Lattices with Tunable and Controllable Anisotropy

Bioinspired Design of Isotropic Lattices with Tunable and Controllable Anisotropy

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