Hydrodynamic Analysis and Verification of an Innovative Whale Shark-like Underwater Glider

doi:10.1007/s42235-020-0010-y

Journal of Bionic Engineering ›› 2020, Vol. 17 ›› Issue (1): 123-133.doi: 10.1007/s42235-020-0010-y

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Hydrodynamic Analysis and Verification of an Innovative Whale Shark-like Underwater Glider

Huijie Dong1,2, Zhengxing Wu1,2, Min Tan1,2, Junzhi Yu1,3*#br#

#br#

1. State Key Laboratory of Management and Control for Complex Systems, Institute of Automation, Chinese Academy of Sciences,
Beijing 100190, China
2. University of Chinese Academy of Sciences, Beijing 100049, China
3. State Key Laboratory for Turbulence and Complex Systems, Department of Mechanics and Engineering Science, BIC-ESAT,
College of Engineering, Peking University, Beijing 100871, China

Received:2019-11-07 Revised:2019-12-01 Accepted:2019-12-12 Online:2020-01-10 Published:2020-01-21
Contact: Junzhi Yu E-mail:junzhi.yu@ia.ac.cn
About author:Huijie Dong1,2, Zhengxing Wu1,2, Min Tan1,2, Junzhi Yu1,3*

Abstract

Abstract: This paper presents an innovative design for a biomimetic whale shark-like underwater glider aiming at the combination of high
maneuverability and long duration. As a hybrid of the underwater glider and the robotic fish, its pectoral fins and tail can serve as not only
the external control surfaces for attitude regulation during gliding but also the propellers for agile fish-like swimming mode. To verify the
gliding capability of the whale shark-like glider and prepare for future dynamic analysis, the hydrodynamic coefficients, including drag,
lift, sliding force, and corresponding moments are estimated through computational fluid dynamics method. In addition, the hydrodynamic
analyses of the proposed glider and an equivalent conventional glider during steady gliding motion are executed for comparison. Extended
experiments are performed to verify the downward gliding performance. The results reveal that the whale shark-like glider has less drag
as well as higher lift-to-drag ratio and a markable gliding capability in practice. It may offer important inspiration for improving the gliding
efficiency and performance of an underwater glider in biomimetic shape design.

Key words: biomimetic robot, CFD, hydrodynamic analysis, underwater glider

Huijie Dong, Zhengxing Wu, Min Tan, Junzhi Yu. Hydrodynamic Analysis and Verification of an Innovative Whale Shark-like Underwater Glider[J].Journal of Bionic Engineering, 2020, 17(1): 123-133.

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[3]	Xueguang Meng, Yanpeng Liu, Mao Sun. Aerodynamics of Ascending Flight in Fruit Flies [J]. Journal of Bionic Engineering, 2017, 14(1): 75-87.
[4]	Xiaoliang Wang, Binbin Xuan. Propulsive Characteristics of Twin Oscillating Airfoils [J]. J4, 2016, 13(3): 468-477.
[5]	Han Zhou1, Tianjiang Hu1,2, Kin Huat Low3, Lincheng Shen1\| Zhaowei Ma1, Guangmi. Bio-inspired Flow Sensing and Prediction for Fish-like Undulating Locomotion: A CFD-aided Approach [J]. J4, 2015, 12(3): 406-417.
[6]	Han Zhou, Tianjiang Hu, Haibin Xie, Daibing Zhang, Lincheng Shen. Computational Hydrodynamics and Statistical Modeling on Biologically Inspired Undulating Robotic Fins: A Two-Dimensional Study [J]. J4, 2010, 7(1): 66-76.
[7]	Gottfried Sachs, Mochammad Agoes Moelyadi. CFD Based Determination of Aerodynamic Effects on Birds with Extremely Large Dihedral [J]. J4, 2010, 7(1): 95-101.
[8]	Ying-xiang Liu; Wei-shan Chen; Jun-kao Liu. Research on the Swing of the Body of Two-Joint Robot Fish [J]. J4, 2008, 5(2): 159-165.
[9]	Yong-hua Zhang¹; Yan Song¹; Jie Yang¹; K. H. Low². Numerical and Experimental Research on Modular Oscillating Fin [J]. J4, 2008, 5(1): 13-23.
[10]	M. A. Moelyadi¹;G. Sachs². CFD Based Determination of Dynamic Stability Derivatives in Yaw for a Bird [J]. J4, 2007, 4(4): 201-208.
[11]	Yong-hua Zhang¹, Lai-bing Jia¹, Shi-wu Zhang¹, Jie Yang¹, K. H. Low². Computational Research on Modular Undulating Fin for Biorobotic Underwater Propulsor [J]. J4, 2007, 4(1): 25-32.
[12]	D. Adkins, Y. Y. Yan. CFD Simulation of Fish-like Body Moving in Viscous Liquid [J]. J4, 2006, 3(3): 147-153.
[13]	Hu Tian-jiang, Shen Lin-cheng, Gong Pei-ling. CFD Validation of the Optimal Arrangement of the Propulsive Dorsal Fin of Gymnarchus niloticus [J]. J4, 2006, 3(3): 139-146.
[14]	Hu Tian-jiang; Li Fei; Wang Guang-ming; Shen Lin-cheng. Morphological Measurement and Analysis of Gymnarchus Niloticus [J]. J4, 2005, 2(1): 25-31.
[15]	Hao Liu ¹, Naomi Kato ². Computation of Unsteady Flow past a Biomimetic Fin [J]. J4, 2004, 1(2): 108-120.

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