师资队伍

教师名录

程正顺

船舶与海洋工程系

电子邮件:zhengshun.cheng@sjtu.edu.cn
通讯地址:上海市东川路800号木兰船建大楼B729

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] 海洋结构物动力耦合与安全分析,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] 超长浮桥设计与分析,包括海洋环境评估与建模、耦合动力响应分析、极值响应及不确定性评估等

SCI期刊Energies特刊客座主编 2018-2019
20多份国际SCI期刊审稿人,包括海洋工程类期刊(Marine Structures, Ocean Engineering, Engineering Structures, Applied Ocean Research等)和海洋可再生能源类期刊(Renewable Energy, Applied Energy, Wind Energy, Energy等)

[1] 2019-2022 上海交通大学长聘教轨副教授科研启动项目,经费200万,在研,项目负责人
[2] 2019-2020 海洋工程国家重点实验室自主研究课题,时空非均匀环境作用下超大型浮体动力响应特性研究,项目编号GKZD010075,经费12万,结题,项目负责人
[3] 2017-2020天津大学水利工程仿真与安全国家重点实验室开放课题,浮式垂直轴风力机动力响应特性研究,项目编号HESS-1710,经费5万,结题,项目负责人
[4] 2016-2020 挪威公共道路管理局资助项目,Characteristic environmental loads and load effects for ULS and ALS design check of floating bridges,经费831万挪威克朗,技术负责人
[5] 2013-2016 欧盟FP7和挪威研究基金委联合资助项目,Dynamic modelling and analysis of a floating wind turbine concept, and comparison with laboratory test data or field measurements,经费250万挪威克朗,技术负责人

外文期刊论文(* corresponding author)
海洋可再生能源(主要为海上风机)
[1] 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.
[2] 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.
[3] 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.
[4] 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.
[5] 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
[6] 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
[7] 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.
[8] 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.
[9] Tu Y, Cheng Z*, Muskulus M. Global slamming forces on Jacket structures for offshore wind applications. Marine Structures, 2018, 58: 53-72.
[10] 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.
[11] 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.
[12] Tu Y, Cheng Z*, Muskulus M. A global slamming force model on offshore wind Jacket structures. Marine Structures, 2018, 60:201-217.
[13] Tu Y, Cheng Z, Muskulus M. A review of slamming load application to offshore wind turbines from an integrated perspective. Energy Procedia, 2017, 137:346-357.
[14] Koppenol B, Cheng Z*, Gao Z, Ferreira CS, Moan T. A comparison of two fully coupled codes for integrated dynamic analysis of floating vertical axis wind turbines. Energy Procedia, 2017, 137:282-290.
[15] Han Y, Le C*, Ding H, Cheng Z*, Zhang P. Stability and dynamic response analysis of a submerged Tension Leg Platform for offshore wind turbines. Ocean Engineering, 2017, 129:68-82.
[16] Cheng Z*, Madsen HA, Gao Z, Moan T. Aerodynamic modeling of floating vertical axis wind turbines using the actuator cylinder method. Energy Procedia, 2016, 94:531-543.
[17] Cheng Z*, Wang K, Gao Z, Moan T. Dynamic response analysis of three floating wind turbine concepts with a two-bladed Darrieus rotor. Journal of Ocean and Wind Energy, 2015, 2: 213-222.
[18] Cheng Z, Yang J, Hu Z, Xiao L. Frequency/time domain modeling of a direct drive point absorber wave energy converter. Science China-Physics Mechanics & Astronomy, 2014, 57(2): 311-320.


超长浮桥
[19] Cheng Z*, Gao Z, Moan T. Extreme Responses and Associated Uncertainties for a Long End-Anchored Floating Bridge. Engineering Structures, 2020
[20] 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
[21] 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
[22] Cheng Z*, Gao Z, Moan T. Hydrodynamic load modeling and analysis of a floating bridge inhomogeneous wave conditions. Marine Structures, 2018, 59: 122-141.
[23] 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.
[24] 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


[1] 《海洋可再生能源》,授课对象:本科生
[2] 《Scientific Writing, Integrity and Ethics》,授课对象:研究生
[3] 《随机理论及其在海洋工程中的应用》,授课对象:研究生

Moan-Faltinsen Best Paper Award, 2017
Marie Curie ITN fellowship, 2013

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