Journal of Bionic Engineering ›› 2022, Vol. 19 ›› Issue (3): 799-815.doi: 10.1007/s42235-022-00155-7

• • 上一篇    下一篇

Bending Resistance and Anisotropy of Basalt Fibers Laminate Composite with Bionic Helical Structure

Binjie Zhang1, Qigang Han2,3, Hanlin Qin2, Junqiu Zhang1,3, Shichao Niu1,3, Zhiwu Han1,3, Luquan Ren1,3   

  1. 1 Key Laboratory of Bionic Engineering (Ministry of Education, China), Jilin University, Changchun 130022, China  2 College of Materials Science and Engineering, Jilin University, Changchun 130022, China  3 Weihai Institute for Bionic, Jilin University, Weihai 264200, China
  • 收稿日期:2021-07-26 修回日期:2021-12-29 接受日期:2021-12-31 出版日期:2022-05-10 发布日期:2022-05-05
  • 通讯作者: Shichao Niu, Zhiwu Han E-mail:niushichao@jlu.edu.cn, zwhan@jlu.edu.cn
  • 作者简介:Binjie Zhang1, Qigang Han2,3, Hanlin Qin2, Junqiu Zhang1,3, Shichao Niu1,3, Zhiwu Han1,3, Luquan Ren1,3

Bending Resistance and Anisotropy of Basalt Fibers Laminate Composite with Bionic Helical Structure

Binjie Zhang1, Qigang Han2,3, Hanlin Qin2, Junqiu Zhang1,3, Shichao Niu1,3, Zhiwu Han1,3, Luquan Ren1,3   

  1. 1 Key Laboratory of Bionic Engineering (Ministry of Education, China), Jilin University, Changchun 130022, China  2 College of Materials Science and Engineering, Jilin University, Changchun 130022, China  3 Weihai Institute for Bionic, Jilin University, Weihai 264200, China
  • Received:2021-07-26 Revised:2021-12-29 Accepted:2021-12-31 Online:2022-05-10 Published:2022-05-05
  • Contact: Shichao Niu, Zhiwu Han E-mail:niushichao@jlu.edu.cn, zwhan@jlu.edu.cn
  • About author:Binjie Zhang1, Qigang Han2,3, Hanlin Qin2, Junqiu Zhang1,3, Shichao Niu1,3, Zhiwu Han1,3, Luquan Ren1,3

摘要: The appendages of mantis shrimp often bear bending loads from different directions during the in the process of preying on prey with its grazing limb. Hence, it has excellent bending resistance and isotropy to confront complex and changeable external load. The outstanding performance owes to the helical Bouligand structure with a certain interlayer corner, which is also widely found in other natural materials. Hence, the bio-inspired materials with basalt fiber are fabricated with outstanding bending resistance, isotropy and toughness. The research shows laminates with 18° interlayer corners exhibit relatively excellent bending resistance and isotropy, and the laminate with 11.25° interlayer corner has best toughness. Compared with traditional composites, average bending strength along different loading direction of bio-inspired materials increased by 28%, and anisotropy decreased by 86%. Besides, the maximum toughness of laminates can increase to 1.7 times of the original. Following the introduction of interlayer corners, the bio-inspired composite tends to be isotropic. To explore the reason for the change of the isotropic performance caused by diverse interlayer corners, the Finite Element Analysis based on classical laminate theory and Tsai–Wu and Tsai–Hill failure criterion. Besides, further experiments and observations are conducted to explore possible reasons. In conclusion, following the introduction of interlayer corners, the bio-inspired composites tend to be isotropic. This bio-inspired composites are expected to be applied to various complex modern engineering fields, such as vehicle, rail transit and aerospace.

关键词: Helical Bouligand structure, Bio-inspired composites, Bending resistance, Isotropy

Abstract: The appendages of mantis shrimp often bear bending loads from different directions during the in the process of preying on prey with its grazing limb. Hence, it has excellent bending resistance and isotropy to confront complex and changeable external load. The outstanding performance owes to the helical Bouligand structure with a certain interlayer corner, which is also widely found in other natural materials. Hence, the bio-inspired materials with basalt fiber are fabricated with outstanding bending resistance, isotropy and toughness. The research shows laminates with 18° interlayer corners exhibit relatively excellent bending resistance and isotropy, and the laminate with 11.25° interlayer corner has best toughness. Compared with traditional composites, average bending strength along different loading direction of bio-inspired materials increased by 28%, and anisotropy decreased by 86%. Besides, the maximum toughness of laminates can increase to 1.7 times of the original. Following the introduction of interlayer corners, the bio-inspired composite tends to be isotropic. To explore the reason for the change of the isotropic performance caused by diverse interlayer corners, the Finite Element Analysis based on classical laminate theory and Tsai–Wu and Tsai–Hill failure criterion. Besides, further experiments and observations are conducted to explore possible reasons. In conclusion, following the introduction of interlayer corners, the bio-inspired composites tend to be isotropic. This bio-inspired composites are expected to be applied to various complex modern engineering fields, such as vehicle, rail transit and aerospace.

Key words: Helical Bouligand structure, Bio-inspired composites, Bending resistance, Isotropy