教师名录

1987年生，博士，副教授，博士生导师

教育背景：
2013.06-2016.06 挪威科技大学 海洋工程 博士
2010.09-2013.03 上海交通大学 船舶与海洋工程 硕士
2006.09-2010.07 上海交通大学 船舶与海洋工程 本科

工作经历：
2019.05-至今 上海交通大学 船舶与海洋工程系 长聘教轨副教授，博士生导师
2016.06-2019.04 挪威科技大学 海洋工程系 博士后
2015.08-2015.10 丹麦技术大学 风能系 访问学者

1. 海洋工程结构动力分析与安全评估，包括多物理场耦合动力分析、随机动力分析、可靠性与不确定性评估等

2. 海上风机技术，包括基础设计、非定常气动载荷、非线性水动力载荷、控制设计、一体化全耦合分析、漂浮式风机新概念等

3. 新型海洋结构物设计与分析，包括超大型浮桥、深远海养殖装备、漂浮式光伏等

• 国家自然科学基金同行评审专家

• 教育部学位与研究生教育发展中心论文评审专家

• 国际SCI期刊Frontiers in Energy Research副主编（2021-现在）

• 国际SCI期刊Ocean Engineering客座编辑（2022-2023）

• Advances in Bridge Engineering客座编辑（2020,2023）

1. 国家重点研发计划政府间国际科技创新合作项目，2023YFE0110000

2. 国家自然科学基金面上项目，42176210

3. 国家自然科学基金青年项目，52201330

4. 国家级青年人才项目

5. 三亚崖州湾科技城管理局重点项目

ResearchGate 主页: https://www.researchgate.net/profile/Zhengshun_Cheng

Google Scholar主页: https://scholar.google.com/citations?user=UcyFd6EAAAAJ&hl=en

外文期刊论文(* corresponding author)
海洋可再生能源（主要为海上风机）

1. Yang C, Cheng Z*, Xiao L, Tian X, Liu M, Wen B. A gradient-descent-based method for design of performance-scaled rotor for floating wind turbine model testing in wave basins. Renewable Energy, 2022, 187:144-155

2. Yu Z*, Amdahl J, Rypestøl M, Cheng Z. Numerical modelling and dynamic response analysis of a 10 MW semi-submersible floating offshore wind turbine subjected to ship collision loads. Renewable Energy, 2022, 184:677-699

3. Li X, Wei H*, Xiao L, Cheng Z, Liu M. Study on the effects of mooring system stiffness on air gap response. Ocean Engineering, 2021, 239:10979

4. Cao Q, Xiao L*, Cheng Z, Liu M. Dynamic responses of a 10 MW semi-submersible wind turbine at an intermediate water depth: A comprehensive numerical and experimental comparison. Ocean Engineering, 2021, 232: 109138

5. Cao Q, Xiao L*, Cheng Z, Liu M, Wen B. Operational and extreme responses of a new concept of 10MW semi-submersible wind turbine in intermediate water depth: An experimental study. Ocean Engineering, 2020, 217:10800

6. Cheng Z*, Madsen HA, Gao Z, Moan T. A fully coupled method for numerical modeling and dynamic analysis of floating vertical axis wind turbines. Renewable Energy, 2017, 107: 604-619.

7. Cheng Z*, Madsen HA, Chai W, Gao Z, Moan T. A comparison of extreme structural responses and fatigue damage of semi-submersible type floating horizontal and vertical axis wind turbines. Renewable Energy, 2017, 108:207-219.

8. Cheng Z*, Madsen HA, Gao Z, Moan T. Effect of the number of blades on the dynamics of floating straight-bladed vertical axis wind turbines. Renewable Energy, 2017, 101:1285-1298.

9. Cheng Z*, Wang K, Gao Z, Moan T. A comparative study on dynamic responses of spar-type floating horizontal and vertical axis wind turbines. Wind Energy, 2017, 20(2):305-323.

10. Cheng Z, Wen TR, Ong MC, Wang K*. Power performance and dynamic responses of a combined floating vertical axis wind turbine and wave energy converter concept. Energy, 2019, 171: 190-204

11. Zhao Y*, Cheng Z, Gao Z, Sandvik PC, Moan T. Numerical study on the feasibility of offshore single blade installation by floating crane vessels. Marine Structures, 2019, 64: 442-462

12. Zhao Y, Cheng Z*, Sandvik PC, Gao Z, Moan T, Buren, EV. Numerical modeling and analysis of the dynamic motion response of an offshore wind turbine blade during installation by a jack-up crane vessel. Ocean Engineering, 2018, 165:353-364.

13. Zhao Y, Cheng Z*, Sandvik PC, Gao Z, Moan T. An integrated dynamic analysis method for simulating installation of single blades for wind turbines. Ocean Engineering, 2018, 152:72-88.

14. Tu Y, Cheng Z*, Muskulus M. Global slamming forces on Jacket structures for offshore wind applications. Marine Structures, 2018, 58: 53-72.

15. Cheng Z*, Wang K, Ong MC. Assessment of performance enhancement of a semi-submersible vertical axis wind turbine with an optimized Darrieus rotor. Engineering Structures, 2018, 167: 227-240.

16. Li L, Cheng Z, Yuan Z*, Gao Y. Short-term extreme response and fatigue damage of an integrated wind, wave and tidal energy system. Renewable Energy, 2018, 126:617-629.

17. Tu Y, Cheng Z*, Muskulus M. A global slamming force model on offshore wind Jacket structures. Marine Structures, 2018, 60:201-217.

超长浮桥

1. Cui M, Cheng Z*, Moan T. A Generic Method for Assessment of Inhomogeneous Wave Load Effects of Very Long Floating Bridges. Marine Structures. 2022, 83:103186

2. Cheng Z*, Svangstu E, Gao Z, Moan T. Assessment of inhomogeneity in environmental conditions in a Norwegian fjord for design of floating bridges. Ocean Engineering, 2021, 220:108474
   

3. Cheng Z*, Gao Z, Moan T. Extreme Responses and Associated Uncertainties for a Long End-Anchored Floating Bridge. Engineering Structures, 2020, 219, 110858

4. Cheng Z*, Svangstu E, Gao Z, Moan T. Long-term joint distribution of environmental conditions in a Norwegian fjord for design of floating bridges. Ocean Engineering, 2019, 191, 106472

5. Cheng Z*, Gao Z, Moan T. Numerical modeling and dynamic response analysis of a floating bridge subjected to wind, wave and current loads. Journal of Offshore Mechanics and Arctic Engineering, 2019, 141 (1): 011601

6. Cheng Z*, Gao Z, Moan T. Hydrodynamic load modeling and analysis of a floating bridge inhomogeneous wave conditions. Marine Structures, 2018, 59: 122-141.

7. Cheng Z*, Gao Z, Moan T. Wave load effect analysis of a floating bridge in a fjord considering inhomogeneous wave conditions. Engineering Structures, 2018, 163:197-214.

8. Cheng Z*, Svangstu E, Gao Z, Moan T. Field measurements of inhomogeneous wave conditions in Bjørnafjorden. Journal of Waterway, Port, Coastal, and Ocean Engineering, 2019, 145(1):05018008

课程教学：

 [1]    《船舶与海洋工程导论》，NAOE2301，授课对象：本科生

 [2]    《海洋结构物动力学》，NAOE4308，授课对象：本科生

 [3]    《Scientific Writing, Integrity and Ethics》，GE6001，授课对象：研究生

 [4]    《随机理论及其在海洋工程中的应用》，NAOE9107，授课对象：研究生

 [5]    《海上风机设计与分析》，NAOE8124，授课对象：研究生

1. OMAE Conference Best Paper Award, 2023

2. Moan-Faltinsen Best Paper Award, 2017

3. Marie Curie ITN fellowship, 2013