代表性论文专著
2022
(20) Design, modeling and performance analysis of a deployable WEC for ocean robots. Applied energy. revision
(19) Design and Analysis of Double-layer Deployable Unit Based on Hybrid Mechanism. Mechanism and Machine Theory, revision.
(18) Performance analysis of the SJTU-WEC based on the wave-to-wire model and the wave tank experiment, Ocean Engineering, revision.
(17) Experimental and numerical studies on the torsion stiffness effect of a semi-active flapping hydrofoil propulsion, Ocean Engineering, revision.
(16) GuoLiu,HongliDong,WeixingChen*,WeidongZhang, Two unified adaptive control approaches of uncertain delayed nonlinear systems, Journal of The Franklin Institute,2022
(15) Botao Dong; Yunfei Lu; Wei Xie; Longyang Huang; Weixing Chen*; Yongliang Yang; Weidong Zhang*, "Robust Performance-Prescribed Attitude Control of Foldable Wave-Energy Powered AUV Using Optimized Backstepping Technique," in IEEE Transactions on Intelligent Vehicles, 2022, doi: 10.1109/TIV.2022.3189009.
(14) Zhang Y, Feng Y, Chen W*, et al. Effect of pivot location on the semi-active flapping hydrofoil propulsion for wave glider from wave energy extraction. Energy, 2022: 124491.
(13) Z Wu, Y Lu, Q Xu, W Chen* , W Zhang, F Gao, Load optimization control of SJTU-WEC based on machine learning, Ocean Engineering, 2022.
(12) Y Zhang, Y Zhou, W Chen*, W Zhang, F Gao, Design, modeling and numerical analysis of a WEC-Glider (WEG), Renewable Energy, 2022.
Before 2022
(11) W. Chen, et al., Efficiency analysis of a 3-DOF wave energy converter (SJTU-WEC) based on modeling, simulation and experiment. Energy, 2021: p. 119718.
(10) W. Chen, X. Meng, Ye. Li, F. Gao., Type synthesis of parallel mechanisms capturing wave energy. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2019, 0954406219866466.
(9) W. Chen, F. Gao, X. Meng, B. Chen, and A. Ren, "W2P: A high-power integrated generation unit for offshore wind power and ocean wave energy," Ocean Engineering, vol. 128, pp. 41-47, 2016.
(8) W. Chen, F. Gao, X. Meng, and J. Fu, "Design of the wave energy converter array to achieve constructive effects," Ocean Engineering, vol. 124, pp. 13-20, 2016.
(7) W. Chen, F. Gao, X. Meng, A. Ren, and S. Zhou, "An offshore hydraulic wind turbine generator with variable-diameter rotor: Design, modeling and experiment,"Journal of Engineering for the Maritime Environment, 2016.
(6) W. Chen, F. Gao, X. Meng, A. Ren, and Y. Hu, "Power recovery method for testing the efficiency of the ECD of an integrated generation unit for offshore wind power and ocean wave energy," Science China Technological Sciences, pp. 1-12, 2017.
(5) W. Chen, F. Gao, and X. D. Meng, "Oscillating Body Design for A 3-DOF Wave Energy Converter," China Ocean Engineering, vol. 32, no. 4, pp. 453-460, 2018.
(4) W. Chen, F. Gao, and X. Meng, "Kinematics and dynamics of a novel 3-degree-of-freedom wave energy converter," Journal of Engineering for the Maritime Environment, p. 75090218765803, 2018.
(3) W. Chen and F. Gao, "The Principle of an Integrated Generation Unit for Offshore Wind Power and Ocean Wave Energy," in ASME 2017 36th International Conference on Ocean, Offshore and Arctic Engineering, 2017, pp. V010T09A013-V010T09A013: American Society of Mechanical Engineers.
(2) W. Chen, X. Meng, and F. Gao, "The Principle of a Three-DOF Mechanism for Wave Energy Absorption," in ASME 2016 35th International Conference on Ocean, Offshore and Arctic Engineering, 2016, pp. V006T09A030-V006T09A030: American Society of Mechanical Engineers.
(1) W. Chen and F. Gao, The Kinematics of a 3-DOF Mechanism for Wave Energy Converter. Springer Singapore, 2017.