Journal of Bionic Engineering ›› 2020, Vol. 17 ›› Issue (6): 1239-1250.doi: 10.1007/s42235-020-0089-1

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Large Curvature Folding Strategies of Butterfly Proboscis

Daobing Chen1,2, Honglie Song3,2, Qingping Liu2, Jie Gan4, Yang Liu1, Keyu Chen1, Chong Wang1, Shifeng Wen1*, Yan Zhou4*, Chunze Yan1, Junqiu Zhang2, Yusheng Shi1, Zhiwu Han2


  

  1. 1. State Key Laboratory of Material Processing and Die & Mould Technology, Huazhong University of Science and Technology, 
    Wuhan 430074, China
    2. The Key Laboratory of Bionic Engineering (Ministry of Education), Jilin University, Changchun 130022, China
    3. Applied Mechanics Laboratory, Department of Engineering Mechanics, Tsinghua University, Beijing 100083, China
    4. Faculty of Engineering, China University of Geosciences, Wuhan 430074, China

  • 收稿日期:2020-01-31 修回日期:2020-07-07 接受日期:2020-07-13 出版日期:2020-11-10 发布日期:2020-12-17
  • 通讯作者: Shi Feng Wen, Yan Zhou E-mail:roya_wen@hust.edu.cn, zhouyan@cug.edu.cn
  • 作者简介:Daobing Chen1,2, Honglie Song3,2, Qingping Liu2, Jie Gan4, Yang Liu1, Keyu Chen1, Chong Wang1, Shifeng Wen1*, Yan Zhou4*, Chunze Yan1, Junqiu Zhang2, Yusheng Shi1, Zhiwu Han2

Large Curvature Folding Strategies of Butterfly Proboscis

Daobing Chen1,2, Honglie Song3,2, Qingping Liu2, Jie Gan4, Yang Liu1, Keyu Chen1, Chong Wang1, Shifeng Wen1*, Yan Zhou4*, Chunze Yan1, Junqiu Zhang2, Yusheng Shi1, Zhiwu Han2#br#

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  1. 1. State Key Laboratory of Material Processing and Die & Mould Technology, Huazhong University of Science and Technology, 
    Wuhan 430074, China
    2. The Key Laboratory of Bionic Engineering (Ministry of Education), Jilin University, Changchun 130022, China
    3. Applied Mechanics Laboratory, Department of Engineering Mechanics, Tsinghua University, Beijing 100083, China
    4. Faculty of Engineering, China University of Geosciences, Wuhan 430074, China

  • Received:2020-01-31 Revised:2020-07-07 Accepted:2020-07-13 Online:2020-11-10 Published:2020-12-17
  • Contact: Shi Feng Wen, Yan Zhou E-mail:roya_wen@hust.edu.cn, zhouyan@cug.edu.cn
  • About author:Daobing Chen1,2, Honglie Song3,2, Qingping Liu2, Jie Gan4, Yang Liu1, Keyu Chen1, Chong Wang1, Shifeng Wen1*, Yan Zhou4*, Chunze Yan1, Junqiu Zhang2, Yusheng Shi1, Zhiwu Han2

摘要: Due to its real-time control, high folding ratio, and structure self-locking, flexible large curvature self-folding devices have broad application prospects, such as foldable human implants, flexible electronics, and flexible robots. Driven by this background, flexible large curvature folding butterfly (Polyura eudamippus) proboscises were studied in this work. The folding ratio of the proboscises was about 15. The curvature of coiled proboscises ranged from about 150 m?1 to 880 m?1. The external and internal structures of the proboscises were studied by different methods. Three main strategies for large-curvature folding of proboscises were identified: a gradual decrease in thickness, a lower elastic modulus, and (most importantly) large numbers of regular corrugated cracks arranged on the surface. These corrugated cracks can effectively accommodate the coiled strain and provide space for the large curvature folding of proboscises. Finally, a 4D printed coiled sample with corrugated cracks was fabricated to mimic the proboscises stretching process. Large-curvature folding strategies, based on these proboscises, provide insights for the biomimetic design of artificial highly folded components.


关键词: butterfly proboscis, large curvature folding, corrugated crack, 4D printing, bionic

Abstract: Due to its real-time control, high folding ratio, and structure self-locking, flexible large curvature self-folding devices have broad application prospects, such as foldable human implants, flexible electronics, and flexible robots. Driven by this background, flexible large curvature folding butterfly (Polyura eudamippus) proboscises were studied in this work. The folding ratio of the proboscises was about 15. The curvature of coiled proboscises ranged from about 150 m?1 to 880 m?1. The external and internal structures of the proboscises were studied by different methods. Three main strategies for large-curvature folding of proboscises were identified: a gradual decrease in thickness, a lower elastic modulus, and (most importantly) large numbers of regular corrugated cracks arranged on the surface. These corrugated cracks can effectively accommodate the coiled strain and provide space for the large curvature folding of proboscises. Finally, a 4D printed coiled sample with corrugated cracks was fabricated to mimic the proboscises stretching process. Large-curvature folding strategies, based on these proboscises, provide insights for the biomimetic design of artificial highly folded components.


Key words: butterfly proboscis, large curvature folding, corrugated crack, 4D printing, bionic