Effects of nonlinearity of restoring springs on propulsion performance of wave glider

Wave glider is an unmanned surface vehicle that can directly convert wave energy into forward propulsion and fulfill long-term marine monitoring. A previous study suggested that the wave motion and stiffness of restoring springs mounted on the hydrofoil are the main factors affecting the propulsion...

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Veröffentlicht in:	Nonlinear dynamics 2022-05, Vol.108 (3), p.2007-2022
Hauptverfasser:	Feng, Zhanxia, Chang, Zongyu, Deng, Chao, Zhao, Lin, Chen, Jia, Zhang, Jiakun, Zheng, Zhongqiang
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Sprache:	eng
Schlagworte:	Automotive Engineering Classical Mechanics Control Dynamical Systems Engineering Hydrofoils Marine environment Mechanical Engineering Nonlinearity Numerical analysis Original Paper Phase diagrams Pitch (inclination) Propulsion systems Rigid-body dynamics Springs (elastic) Stiffness Surface vehicles Underwater propulsion Unmanned vehicles Velocity Vibration Wave excitation Wave power Waves
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container_end_page	2022
container_issue	3
container_start_page	2007
container_title	Nonlinear dynamics
container_volume	108
creator	Feng, Zhanxia Chang, Zongyu Deng, Chao Zhao, Lin Chen, Jia Zhang, Jiakun Zheng, Zhongqiang
description	Wave glider is an unmanned surface vehicle that can directly convert wave energy into forward propulsion and fulfill long-term marine monitoring. A previous study suggested that the wave motion and stiffness of restoring springs mounted on the hydrofoil are the main factors affecting the propulsion performance of the wave glider. In this paper, the dynamic responses and nonlinear characteristics of the underwater propulsion mechanism considering the nonlinear stiffness of restoring springs are investigated based on a fluid–rigid body coupled model. Firstly, models of propulsion mechanism with different kinds of restoring springs are proposed, and the linear and nonlinear characteristics of the restoring spring are considered. Then, a fluid–rigid body coupled model of a wave glider is developed by coupling the rigid body dynamics model and hydrodynamic model. Dynamic responses are simulated by the numerical analysis method, and the nonlinear characteristics with different restoring springs are illustrated by the time/frequency domain motion response and phase diagram analysis. The effects of the wave excitation frequency, wave heights and the location of the connection point of springs on the propulsion performance of the wave glider are analyzed. The results show that multi-frequency responses occurred in the propulsion system, and the nonlinear restoring spring on the hydrofoil can provide a larger restoring moment to avoid excessive pitch angle and is more suitable for different sea conditions, which provides a reference for developing propulsion mechanisms with high performance in complex marine environments.
doi_str_mv	10.1007/s11071-022-07295-9
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A previous study suggested that the wave motion and stiffness of restoring springs mounted on the hydrofoil are the main factors affecting the propulsion performance of the wave glider. In this paper, the dynamic responses and nonlinear characteristics of the underwater propulsion mechanism considering the nonlinear stiffness of restoring springs are investigated based on a fluid–rigid body coupled model. Firstly, models of propulsion mechanism with different kinds of restoring springs are proposed, and the linear and nonlinear characteristics of the restoring spring are considered. Then, a fluid–rigid body coupled model of a wave glider is developed by coupling the rigid body dynamics model and hydrodynamic model. Dynamic responses are simulated by the numerical analysis method, and the nonlinear characteristics with different restoring springs are illustrated by the time/frequency domain motion response and phase diagram analysis. The effects of the wave excitation frequency, wave heights and the location of the connection point of springs on the propulsion performance of the wave glider are analyzed. 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A previous study suggested that the wave motion and stiffness of restoring springs mounted on the hydrofoil are the main factors affecting the propulsion performance of the wave glider. In this paper, the dynamic responses and nonlinear characteristics of the underwater propulsion mechanism considering the nonlinear stiffness of restoring springs are investigated based on a fluid–rigid body coupled model. Firstly, models of propulsion mechanism with different kinds of restoring springs are proposed, and the linear and nonlinear characteristics of the restoring spring are considered. Then, a fluid–rigid body coupled model of a wave glider is developed by coupling the rigid body dynamics model and hydrodynamic model. Dynamic responses are simulated by the numerical analysis method, and the nonlinear characteristics with different restoring springs are illustrated by the time/frequency domain motion response and phase diagram analysis. 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subjects	Automotive Engineering Classical Mechanics Control Dynamical Systems Engineering Hydrofoils Marine environment Mechanical Engineering Nonlinearity Numerical analysis Original Paper Phase diagrams Pitch (inclination) Propulsion systems Rigid-body dynamics Springs (elastic) Stiffness Surface vehicles Underwater propulsion Unmanned vehicles Velocity Vibration Wave excitation Wave power Waves
title	Effects of nonlinearity of restoring springs on propulsion performance of wave glider
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