Journal of Bionic Engineering ›› 2023, Vol. 20 ›› Issue (4): 1670-1686.doi: 10.1007/s42235-023-00358-6

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Design and Analysis of Energy Absorbent Bioinspired Lattice Structures

Lucrezia Greco1; Federica Buccino1; Zhuo Xu2; Laura Vergani1; Filippo Berto3; Mario Guagliano1; Seyyed Moahmmad Javad Razavi2; Sara Bagherifard1   

  1. 1 Department of Mechanical Engineering, Politecnico di Milano, Milan, Italy  2 Department of Mechanical and Industrial Engineering, Norwegian University of Science and Technology, Trondheim, Norway  3 Chemical Engineering and Materials Environment Department, Sapienza University of Rome, Rome, Italy
  • 出版日期:2023-07-10 发布日期:2023-07-10
  • 通讯作者: Sara Bagherifard E-mail:sara.bagherifard@polimi.it
  • 作者简介:Lucrezia Greco, Federica Buccino, Zhuo Xu, Laura Vergani, Filippo Berto, Mario Guagliano, Seyyed Moahmmad Javad Razavi & Sara Bagherifard

Design and Analysis of Energy Absorbent Bioinspired Lattice Structures

Lucrezia Greco1; Federica Buccino1; Zhuo Xu2; Laura Vergani1; Filippo Berto3; Mario Guagliano1; Seyyed Moahmmad Javad Razavi2; Sara Bagherifard1   

  1. 1 Department of Mechanical Engineering, Politecnico di Milano, Milan, Italy  2 Department of Mechanical and Industrial Engineering, Norwegian University of Science and Technology, Trondheim, Norway  3 Chemical Engineering and Materials Environment Department, Sapienza University of Rome, Rome, Italy
  • Online:2023-07-10 Published:2023-07-10
  • Contact: Sara Bagherifard E-mail:sara.bagherifard@polimi.it
  • About author:Lucrezia Greco, Federica Buccino, Zhuo Xu, Laura Vergani, Filippo Berto, Mario Guagliano, Seyyed Moahmmad Javad Razavi & Sara Bagherifard

摘要: The increasing demand for energy absorbent structures, paired with the need for more efficient use of materials in a wide range of engineering fields, has led to an extensive range of designs in the porous forms of sandwiches, honeycomb, and foams. To achieve an even better performance, an ingenious solution is to learn how biological structures adjust their configurations to absorb energy without catastrophic failure. In this study, we have attempted to blend the shape freedom, offered by additive manufacturing techniques, with the biomimetic approach, to propose new lattice structures for energy absorbent applications. To this aim we have combined multiple bio-inspirational sources for the design of optimized configurations under compressive loads. Periodic lattice structures are fabricated based on the designed unit cell geometries and studied using experimental and computational strategies. The individual effect of each bio-inspired feature has been evaluated on the energy absorbance performance of the designed structure. Based on the design parameters of the lattices, a tuning between the strength and energy absorption could be obtained, paving the way for transition within a wide range of real-life applicative scenarios.

关键词:  , Energy absorbance , · Lattice structures , · Bio-inspiration , · Fused deposition modeling , · Lightweight design

Abstract: The increasing demand for energy absorbent structures, paired with the need for more efficient use of materials in a wide range of engineering fields, has led to an extensive range of designs in the porous forms of sandwiches, honeycomb, and foams. To achieve an even better performance, an ingenious solution is to learn how biological structures adjust their configurations to absorb energy without catastrophic failure. In this study, we have attempted to blend the shape freedom, offered by additive manufacturing techniques, with the biomimetic approach, to propose new lattice structures for energy absorbent applications. To this aim we have combined multiple bio-inspirational sources for the design of optimized configurations under compressive loads. Periodic lattice structures are fabricated based on the designed unit cell geometries and studied using experimental and computational strategies. The individual effect of each bio-inspired feature has been evaluated on the energy absorbance performance of the designed structure. Based on the design parameters of the lattices, a tuning between the strength and energy absorption could be obtained, paving the way for transition within a wide range of real-life applicative scenarios.

Key words:  , Energy absorbance , · Lattice structures , · Bio-inspiration , · Fused deposition modeling , · Lightweight design