Journal of Bionic Engineering ›› 2019, Vol. 16 ›› Issue (5): 916-930.doi: 10.1007/s42235-019-0106-4

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Bionic Flapping Pectoral Fin with Controllable Spatial Deformation

Yueri Cai1,2*, Lingkun Chen1, Shusheng Bi1, Guoyuan Li2, Houxiang Zhang2   

  1. 1. Robotics Institute, Beihang University, Beijing 100191, China
    2. Department of Ocean Operations and Civil Engineering, Norwegian University of Science and Technology, 
    Aalesund 6025, Norway

  • 收稿日期:2019-09-22 修回日期:2019-06-13 接受日期:2019-07-30 出版日期:2019-10-10 发布日期:2019-10-15
  • 通讯作者: Yueri Cai E-mail:caiyueri@buaa.edu.cn
  • 作者简介:Yueri Cai, Lingkun Chen, Shusheng Bi, Guoyuan Li, Houxiang Zhang

Bionic Flapping Pectoral Fin with Controllable Spatial Deformation

Yueri Cai1,2*, Lingkun Chen1, Shusheng Bi1, Guoyuan Li2, Houxiang Zhang2   

  1. 1. Robotics Institute, Beihang University, Beijing 100191, China
    2. Department of Ocean Operations and Civil Engineering, Norwegian University of Science and Technology, 
    Aalesund 6025, Norway

  • Received:2019-09-22 Revised:2019-06-13 Accepted:2019-07-30 Online:2019-10-10 Published:2019-10-15
  • Contact: Yueri Cai E-mail:caiyueri@buaa.edu.cn
  • About author:Yueri Cai, Lingkun Chen, Shusheng Bi, Guoyuan Li, Houxiang Zhang

摘要: This paper presents the design of a bionic pectoral fin with fin rays driven by multi-joint mechanism. Inspired by the cownose ray, the bionic pectoral fin is modeled and simplified based on the key structure and movement parameters of the cownose ray’s pectoral fin. A novel bionic propulsion fin ray composed of a synchronous belt mechanism and a slider-rocker mechanism is designed and optimized in order to minimize the movement errors between the designed fin rays and the spanwise curves observed from the cownose ray, and thereby reproducing an actively controllable flapping deformation. A bionic flapping pectoral fin prototype is developed accordingly. Observations verify that the bionic pectoral fin flaps consistently with the design rule extracted from the cownose ray. Experiments in a towing tank are set up to test its capability of generating the lift force and the propulsion force. The movement parameters within the usual propulsion capabilities of the bionic pectoral fin are utilized: The flapping frequency of 0.2 Hz – 0.6 Hz, the flapping amplitude of 3? – 18?, and the phase difference of 10? – 60?. The results show that the bionic pectoral fin with actively controllable spatial deformation has expected propulsion performance, which supports that the natural features of the cownose ray play an important role in designing and developing a bionic prototype.


关键词: cownose ray, bionic pectoral fin, controllable deformation, multiple fin rays, propulsion performance

Abstract: This paper presents the design of a bionic pectoral fin with fin rays driven by multi-joint mechanism. Inspired by the cownose ray, the bionic pectoral fin is modeled and simplified based on the key structure and movement parameters of the cownose ray’s pectoral fin. A novel bionic propulsion fin ray composed of a synchronous belt mechanism and a slider-rocker mechanism is designed and optimized in order to minimize the movement errors between the designed fin rays and the spanwise curves observed from the cownose ray, and thereby reproducing an actively controllable flapping deformation. A bionic flapping pectoral fin prototype is developed accordingly. Observations verify that the bionic pectoral fin flaps consistently with the design rule extracted from the cownose ray. Experiments in a towing tank are set up to test its capability of generating the lift force and the propulsion force. The movement parameters within the usual propulsion capabilities of the bionic pectoral fin are utilized: The flapping frequency of 0.2 Hz – 0.6 Hz, the flapping amplitude of 3? – 18?, and the phase difference of 10? – 60?. The results show that the bionic pectoral fin with actively controllable spatial deformation has expected propulsion performance, which supports that the natural features of the cownose ray play an important role in designing and developing a bionic prototype.


Key words: cownose ray, bionic pectoral fin, controllable deformation, multiple fin rays, propulsion performance