张显涛 船舶与海洋工程系
办公电话：
电子邮件：zhxt@sjtu.edu.cn; zhxter@outlook.com
通讯地址：上海市闵行区东川路800号木兰船建大楼B315
个人主页：https://www.researchgate.net/profile/Xiantao_Zhang；https://scholar.google.com/citations?user=GmvU9J7nfX8C&hl=en


个人简历 研究方向 学术兼职 科研项目 代表性论文及专著 教学工作 软件版权登记及专利 荣誉和奖励
博士，助理教授，硕士生、博士生导师
工作经历：
2018年12月-至今， 上海交通大学，长聘教轨助理教授
教育经历：
2015年-2018年， 西澳大利亚大学，海洋工程专业，博士
2012年-2015年，上海交通大学，海洋工程专业，硕士
2008年-2012年，上海交通大学，海洋工程专业，学士


[1] 海洋波浪能开发利用技术，研究内容包括：水动力分析，控制算法与应用，非线性能量捕获机制，模型与实尺度试验技术研究等。
[2] 超大型浮式结构物动力响应理论与实验，包括：超大型浮体的水弹性响应理论与应用，极端海况下越浪机理与预报、冰层覆盖区的水动力响应等
[3] 深远海渔业养殖装备：聚焦在浮圈-网衣、半潜式、浸没式、船型等养殖结构的流场分析、流固耦合响应理论与实验技术等。


担任20多份SCI期刊审稿人，https://publons.com/researcher/**/xiantao-zhang/。包括海洋工程类期刊（Ocean Engineering, Applied Ocean Research, Engineering Structures, Journal of Port, Waterway, Coastal and Ocean Engineering, China Ocean Engineering, International Journal of Offshore and Polar Engineering, Ships and Offshore Structures, Journal of Marine Science and Engineering, Journal of Ocean Engineering and Science等）和海洋可再生能源类期刊（Applied Energy, Energy，Renewable Energy, Renewable and Sustainable Energy Reviews, IEEE transactions on Sustainable Energy, IEEE Access, Energies, Water, Sustainability等）。
担任国家自然科学基金评审专家，海南省自然科学基金评审专家。


[7] 海岸和近海工程国家重点实验室开放基金项目，极端波浪下计及越浪效应的超大型浮体非线性动力响应特性研究，2020.8-2022.7，在研，主持
[6] 海洋工程国家重点实验室自主研究课题，深远海超大型浮式基地非线性动力响应预报研究，2020.7-2021.3， 15万元，在研，主持
[5] 上海市浦江人才计划项目, 极端海况下深水船型浮式结构物甲板上浪机理与砰击特性研究，2019.10-2021.9，30万元，在研，主持
[4] 上海交通大学长聘教轨助理教授科研启动项目，新型适应型双稳态浮子式波浪能装置关键问题研究，2018.12-2021.12，20万，在研，主持
[3] 三亚崖州湾科技城管理局科研项目，深远海浮子式波浪能发电装置高效俘能技术与复杂动力特性研究，2020.9-2022.9，200万，在研，主持
[2] 上海市科委"科技创新行动计划"，深海矿产资源开发关键技术，2019.7-2022.6，2600万，在研，参加（子课题技术负责人，集矿系统研发）
[1] 澳大利亚政府研究理事会与伍德赛德石油公司，壳牌石油公司，法国船级社和劳氏船级社等联合项目, 极端海况下的FPSO甲板上浪机理与预报，2015.5-2018.12，结题，参加（技术负责人）。


1. 海洋波浪能开发利用技术 （*代表通讯作者）
[12] Yang Song, Xiaoxian Guo, Hongchao Wang, Xinliang Tian, Handi Wei, Xiantao Zhang*, 2020. Perfomance analysis of an adaptive bistable point absorber wave energy converter under white noise wave excitation, IEEE Transactions on Sustainable Energy, available online.
[11] Lu Da, Tian Xinliang, Lu Wenyue. and Zhang Xiantao*, 2019. Combined effects of raft length ratio and structural flexibility on power capture performance of an interconnected-two-raft wave energy converter. Ocean Engineering, 177, pp.12-28.
[10] Li Liang, Zhang Xiantao, Yuan Zhiming* and Gao Yan, 2019. Multi-stable mechanism of an oscillating-body wave energy converter. IEEE Transactions on Sustainable Energy,11(1), pp.500-508.
[9] Zhang Xiantao, Tian Xinliang, Xiao Longfei, Li Xin and Lu Wenyue*, 2019. Mechanism and sensitivity for broadband energy harvesting of an adaptive bistable point absorber wave energy converter. Energy, 188, p.115984.
[8] Zhang Xiantao*, Tian Xinliang, Xiao Longfei, Li Xin and Chen Lifen, 2018. Application of an adaptive bistable power capture mechanism to a point absorber wave energy converter. Applied Energy, 228, pp.450-467.
[7] Zhang Xiantao*, Lu Da, Guo Fei, Gao Yun and Sun Yonggang, 2018. The maximum wave energy conversion by two interconnected floaters: Effects of structural flexibility. Applied Ocean Research, 71, pp.34-47.
[6] Zhang Xiantao, Yang Jianmin and Xiao Longfei, 2016. An oscillating wave energy converter with nonlinear snap-through Power-Take-Off systems in regular waves. China Ocean Engineering, 30(4), pp.565-580.
[5] Zhang Xiantao, Yang Jianmin*, Zhao Wenhua and Xiao Longfei, 2016. Effects of wave excitation force prediction deviations on the discrete control performance of an oscillating wave energy converter. Ships and Offshore Structures, 11(4), pp.351-368.
[4] Zhang Xiantao* and Yang Jianmin, 2015. Power capture performance of an oscillating-body WEC with nonlinear snap through PTO systems in irregular waves. Applied Ocean Research, 52, pp.261-273.
[3] Wang Peng, Zhang Xiantao, Wang Daoyong, Guo Xiaoxian, Lu Wenyue and Tian Xinliang*, 2020. A restricted circle based position keeping strategy for the wave glider. Applied Ocean Research, 97, p.102081.
[2] Wang Peng, Wang Daoyong, Zhang Xiantao, Guo Xiaoxian, Li Xin and Tian Xinliang*, 2019. Path following control of the wave glider in waves and currents. Ocean Engineering, 193, p.106578.
[1] 张显涛, 2015. 振荡浮体式波能发电装置的水动力研究 (Master's thesis, 上海交通大学).
2. 超大型浮式结构物动力响应理论与实验

[10] Xiantao Zhang, Da Lu, Yibo Liang* and Feargal Brennan. 2020. Feasibility of a very large floating structure as an offshore wind foundation: effects of hinge numbers on wave loads and induced responses. Journal of Waterway, Port, Coastal and Ocean Engineering, accepted.
[9] Zhang Xiantao*, Tian Xinliang, Guo Xiaoxian, Li Xin, Xiao Longfei, 2020. Bottom step enlarging horizontal momentum flux of dam break flow. Ocean Engineering (accepted).
[8] Zhang Xiantao*, Zheng Siming, Lu Da and Tian Xinliang, 2019. Numerical investigation of the dynamic response and power capture performance of a VLFS with a wave energy conversion unit. Engineering Structures, 195, pp.62-83.
[7] Lu Wenyue, Li Jun, Li Xin, Tian Xinliang, Wu Xiao and Zhang Xiantao, 2019. Experimental investigation on the statistics of rogue waves under a random wave background. Ocean Engineering, 186, p.106075.
[6] Lu Da, Fu Shixiao*, Zhang Xiantao, Guo Fei and Gao Yun, 2019. A method to estimate the hydroelastic behaviour of VLFS based on multi-rigid-body dynamics and beam bending. Ships and Offshore Structures, 14(4), pp.354-362.
[5] Zhang Xiantao*, Draper Scott, Wolgamot Hugh, Zhao Wenhua and Cheng Liang, 2019. Eliciting features of 2D greenwater overtopping of a fixed box using modified dam break models. Applied Ocean Research, 84, pp.74-91.
[4] Zhang Xiantao, Lu Da, Gao Yun and Chen Lifen, 2018. A time domain discrete-module-beam-bending-based hydroelasticity method for the transient response of very large floating structures under unsteady external loads. Ocean Engineering, 164, pp.332-349.
[3] Zhang Xiantao and Lu Da, 2018. An extension of a discrete-module-beam-bending-based hydroelasticity method for a flexible structure with complex geometric features. Ocean Engineering, 163, pp.22-28.
[2] Sun Yonggang, Lu Da, Xu Jin and Zhang Xiantao, 2018. A study of hydroelastic behavior of hinged VLFS. International Journal of Naval Architecture and Ocean Engineering, 10(2), pp.170-179.
[1] Sun Yonggang and Zhang Xiantao*, 2017. A second order analytical solution of focused wave group interacting with a vertical wall. International Journal of Naval Architecture and Ocean Engineering, 9(2), pp.160-176.
3. 深远海渔业养殖装备

国际国内会议论文
[7] Chen Lifen, Zhang Xiantao, Taylor Paul, Draper Scott and Wolgamot Hugh, 2019, June. CFD Modelling to Investigate Design of a Whaleback-Type Forecastle for Greenwater Protection. In International Conference on Offshore Mechanics and Arctic Engineering (Vol. 58882, p. V009T12A004). American Society of Mechanical Engineers.
[6] Zhang Xiantao, Draper Scott, Wolgamot Hugh, Zhao Wenhua, Chen Lifen and Cheng Liang, 2019, June. CFD Investigations of 2D Greenwater Overtopping of a Floating Offshore Vessel. In International Conference on Offshore Mechanics and Arctic Engineering (Vol. 58882, p. V009T12A012). American Society of Mechanical Engineers.
[5] Zhang Xiantao*, Draper Scott, Wolgamot Hugh, Zhao Wenhua, Cheng Liang, 2018. Numerical investigation of effects of bow flare angles on greenwater overtopping a fixed offshore vessel. The 37th International Conference on Ocean, Offshore and Arctic Engineering, in Madrid, Spain.
[4] Zhang Xiantao*, Wolgamot Hugh, Draper Scott, Zhao Wenhua and Cheng Liang, 2018. The role of overtopping duration in greenwater loading. The 33rd International Workshop on Water Waves and Floating Bodies, in Guidel-Plages, France.
[3] Kurniawan Adi. and Zhang Xiantao, 2018, July. Application of a negative stiffness mechanism on pitching wave energy devices. In 5th Offshore Energy and Storage Symposium.
[2] Zhang, Xiantao*, Draper Scott, Wolgamot Hugh, Zhao Wenhua, Cheng Liang, 2016. Numerical Investigation of Green Water for A Two Dimensional Fixed Rectangular Structure. The 20th Australia Fluid Mechanics Conference, Perth, Australia, 5-8 December, 2016.
[1] Zhang Xiantao*, Yang Jianmin and Xiao Longfei, 2014. Numerical study of an oscillating wave energy converter with nonlinear snap-through power-take-off systems in regular waves. In The Twenty-fourth International Ocean and Polar Engineering Conference. International Society of Offshore and Polar Engineers.




[4] 《海洋可再生能源》，授课对象：本科生
[3] 《Scientific Writing, Integrity and Ethics》，授课对象：研究生
[2] 第36期PRP项目，极端海况下甲板上浪数值模拟与溃坝预报模型修正
[1] 第37期PRP项目，波浪能驱动深海移动式垂直剖面监测系统概念设计与实验测试


研究生指导：
[6] 张雪燕， 2020级博士，深远海养殖装备
[5] 王瀚斌，2020级博士，深远海养殖装备
[4] 彦祥宇，2020级硕士，波浪能
[3] 宋旸，2020级硕士，波浪能
[2] 陈永强， 2020级硕士，超大型浮体
[1] 张宇，2019级硕士，超大型浮体




[4] 自适应型双稳态浮子式波浪能发电装置及发电方法，2019.06.07，中国，CNA，（实审，第一发明人）
[3] 用于海洋平台模型振荡试验的多自由度测力装置，2015.10.14，中国，CNB （已授权）
[2] 均匀流下的FISHFARM浮筒分段模型水平强迫振动实验装置，2013.9.25，中国，CNB（已授权）
[1] 均匀流下的FISHFARM浮筒分段模型双向强迫振动实验装置，2013.6.19，中国，CNB （已授权）


2019年上海市浦江人才计划
2019年第二届上海市青少年人工智能创新大赛一等奖，获优秀指导教师奖
2019年第八届全国海洋航行器设计与制作大赛一等奖，指导老师
2019年首钢京唐杯第十二届全国大学生节能减排社会实践与科技竞赛 三等奖，指导老师
第33届水波与浮体国际研讨会Tuck Fellowship;
第31届OMAE国际会议Outreach to Engineers 资助；
澳洲政府国际研究奖学金；西澳大学-壳牌石油公司杰出研究奖学金