Numerical Study on Helical Fiber Fragmentation in Chiral Biological Materials 被引量：1

Numerical Study on Helical Fiber Fragmentation in Chiral Biological Materials

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摘要 Chiral microstructures exist widely in natural biological materials such as wood, bone, and climbing tendrils. The helical shape of such microstructures plays an important role in stress transfer between fiber and matrix,and in the mechanical properties of biological materials. In this paper, helical fiber fragmentation behavior is studied numerically using the finite-element method(FEM), and then, the effects of helical shape on fiber deformation and fracture,and the corresponding mechanical mechanisms are investigated. The results demonstrate that, to a large degree, the initial microfibril angle(MFA) determines the elastic deformation and fracture behavior of fibers. For fibers with a large MFA, the interfacial area usually has large values, inducing a relatively low fragment density during fiber fragmentation. This work may be helpful in understanding the relationship between microstructure and mechanical property in biological materials, and in the design and fabrication of bio-inspired advanced functional materials. Chiral microstructures exist widely in natural biological materials such as wood, bone, and climbing tendrils. The helical shape of such microstructures plays an important role in stress transfer between fiber and matrix,and in the mechanical properties of biological materials. In this paper, helical fiber fragmentation behavior is studied numerically using the finite-element method(FEM), and then, the effects of helical shape on fiber deformation and fracture,and the corresponding mechanical mechanisms are investigated. The results demonstrate that, to a large degree, the initial microfibril angle(MFA) determines the elastic deformation and fracture behavior of fibers. For fibers with a large MFA, the interfacial area usually has large values, inducing a relatively low fragment density during fiber fragmentation. This work may be helpful in understanding the relationship between microstructure and mechanical property in biological materials, and in the design and fabrication of bio-inspired advanced functional materials.

作者 Jianshan Wang Li Yuan Lixin Wang Yuhong Cui Qinghua Qin

机构地区 Department of Mechanics China Automotive Technology and Research Center Research School of Engineering

出处《Transactions of Tianjin University》 EI CAS 2018年第1期51-58,共8页 天津大学学报（英文版）

基金 supported by the National Natural Science Foundation of China(Nos.11472191,11172207,and 11272230)

关键词 CHIRAL BIOLOGICAL materials HELICAL FIBER FIBER FRAGMENTATION Deformation Dissipated energy Chiral biological materials Helical fiber Fiber fragmentation Deformation Dissipated energy

分类号 G64 [文化科学—高等教育学]

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参考文献2

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2018年第1期

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