船舶与海洋工程系
办公电话:021-34207238
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B803B
个人主页:https://www.researchgate.net/profile/Xiantao_Zhang;https://scholar.google.com/citations?user=GmvU9J7nfX8C&hl=en
博士,副教授,硕士/博士生导师
工作经历:
2023年01月- 至今,上海交通大学,长聘教轨副教授
2018年12月-2022年12月,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
长期欢迎有兴趣的本科生、研究生加入课题组,探索海洋工程与装备领域有趣且有用的研究课题。
海洋浮式装备耦合动力学:
波浪观测(光学、雷达等)、重构与预报;
波浪能俘获技术(应用场景为水面水下无人系统或其他海洋结构);
海上光伏装备与消浪设施;
深远海养殖装备;
波动鳍潜航器等。
国际SCI期刊《Water》编委
《Frontiers in Energy Research》审稿编委
《机器人》青年编委
担任20多份SCI期刊审稿人,https://publons.com/researcher/1174390/xiantao-zhang/
包括:海洋工程类期刊(Ocean Engineering, Applied Ocean Research, Journal of Fluids and Structures, Marine Structures, 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),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),力学类期刊(Nonlinear Dynamics)等。
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,国家学位论文评审专家。
纵向类项目
国家自然科学基金国际合作研究项目金砖专项《气候变化下渔业社区水-能源-食物系统应对策略:集成养殖-海洋能-海水淡化的海上多功能浮式平台可行性研究》,200万,主持
国家自然科学基金面上项目《波流激励下大型浮式薄膜光伏平台全耦合动力学模型与响应机理研究》,主持
国家自然科学基金青年项目《基于适应型双稳态机制的浮子式波浪能装置高效俘能特性研究》,主持
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》,主持
海南省三亚崖州湾科技城管理局重点项目《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》,356.4万,主持
重庆市自然科学基金面上项目《波能利用型深远海养殖网箱耦合动力特性与俘能性能研究》,主持
海南省自然科学基金青年项目《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》,主持
海南省崖州湾科技城自然科学基金联合项目《极端波浪与流作用下深远海养殖装备立柱-网衣组合结构流固耦合动力特性研究》,导师负责
横向类项目
《深水船型浮式结构物甲板上浪实验及瞬态设计波分析验证》,国际合作,主持
《深远海养殖装备立柱-网衣耦合水动力特性试验》,企事业单位委托,主持
《基于风光同场的漂浮式光伏水动力数值及模型试验》,企事业单位委托,主持
《海上薄膜腔型支撑结构设计技术研究》,企事业单位委托,主持
《海上透空薄膜式光伏支撑基础一体化数值模拟软件开发及物理模型试验研究》,企事业单位委托,主持
《大型海上漂浮式结构风浪联合流固耦合分析模型试验及数值对比验证》,企事业单位委托,主持
《模块化浮式防波堤消浪和水动力特性研究》,企事业单位委托,主持
发表期刊论文(*代表通讯作者) (最新统计参考谷歌学术:https://scholar.google.com/citations?user=GmvU9J7nfX8C&hl=en)
2024年度
Liu, Y., Dong, Q., Chen, G. and Zhang, X.*, 2024. Optimized quiescent period prediction under harsh sea states using a linear wave model based on physics-informed neural networks. Ocean Engineering, 310, pp.118763.
Luo, W., Zhang, X.*, Tian, X., Cheng, Z., Wen, B., Li, X. and Luo, Y., 2024. Conceptual design and model test of a pontoon-truss type offshore floating photovoltaic system with soft connection. Ocean Engineering, 309, pp.118518.
Chen, Z., Zhang, X.*, Liu, L., Tian, X. and Li, X., 2024. Dynamic characteristics and energy harvesting performance of self-reacting point absorbers integrated with a mechanical power take-off and a magnetic bistable mechanism. Energy Conversion and Management, 315, pp.118802.
Chen, C., Wang, H., Zhang, X. and Zhang, X., 2024. Hydrodynamic interactions between the cylinder and nets of a typical offshore aquaculture structure in steady current: Numerical investigation and coupling mechanism. Marine Structures, 97, pp.103657.
Ren, X., Chen, Y., Zhang, Y., Zhang, X.*, Shen, K., Cui, L. and Lu, M., 2024. A discrete-module-beam hydroelasticity method with finite element theory in analyzing VLFS in different engineering scenarios. Ocean Engineering, 307, pp.118121.
Zhang, Y., Zhang, X.*, Chen, Y., Tian, X. and Li, X., 2024. A frequency-domain hydroelastic analysis of a membrane-based offshore floating photovoltaic platform in regular waves. Journal of Fluids and Structures, 127, pp.104125.
Liu, Y., Zhang, X., Dong, Q., Chen, G. and Li, X., 2024. Phase-resolved wave prediction with linear wave theory and physics-informed neural networks. Applied Energy, 355, pp.121602.
Chen, Z., Zhang, X.*, Liu, L., Tian, X. and Li, X., 2024. Mechanical property identification and performance evaluation of a power take-off combined with a mechanical motion rectifier and a magnetic bistable device. Applied Energy, 353, pp.122091.
陈永强, 张显涛. 融合有限元理论的DMB方法及其在复杂超大型浮体上的应用[J]. 中国舰船研究, 2024, 19(4): 1–9
2023年度
Liu, L., Zhang, X.*, Tian, X. and Li, X., 2023. Numerical investigation on dynamic performance of vertical hydraulic transport in deepsea mining. Applied Ocean Research, 130, pp.103443.
Wang, H., Zhang, X., Zhang, X.*, Li, X., Tian, X., Shen, Y. and Song, W., 2023. Experimental investigations on hydrodynamic interactions between the cylinder and nets of a typical offshore aquacultural structure in steady current. Marine Structures, 88, pp.103367.
Chen, Y., Zhang, X.*, Shen, K. and Ren, X., 2023. Extension of the discrete-module-finite-element method into the interconnected large floating flexible structures. Ocean Engineering, 269, pp.113549.
Chen, Y., Zhang, X.*, Liu, L., Tian, X., Li, X. and Cheng, Z., 2023. A discrete-module-finite-element hydroelasticity method in analyzing dynamic response of floating flexible structures. Journal of Fluids and Structures, 117, pp.103825.
2022年度
Zhang, X., Lu, D., Dong, H., Zhao, X.*, Brennan, F. and Liang, Y., 2022. Vibration suppression of multi-component floating structures via passive TMDs and Bayesian ascent. Ocean Engineering, 259, pp.112088.
Zhang, X., Zhang, H.*, Zhou, X. and Sun, Z., 2022. Recent advances in wave energy converters based on nonlinear stiffness mechanisms. Applied Mathematics and Mechanics, 43(7), pp.1081-1108.
Chen, Y., Zhang, Y., Tian, X., Guo, X., Li, X. and Zhang, X.*, 2022. A numerical framework for hydroelastic analysis of a flexible floating structure under unsteady external excitations: Motion and internal force/moment. Ocean Engineering, 253, p.111288.
2021年度
Wang, P., Tian, X., Liang, X., Guo, X., Li, X. and Zhang, X.*, 2021. Development of the control system for a wave driven glider. Ocean Engineering, 229, p.108813.
Zhang, X., Lu, D., Liang, Y.* and Brennan, F., 2021. Feasibility of very large floating structure as offshore wind foundation: effects of hinge numbers on wave loads and induced responses. Journal of Waterway, Port, Coastal, and Ocean Engineering, 147(3), pp.04021002.
2020年度
Zhang, X.*, Tian, X., Guo, X., Li, X. and Xiao, L., 2020. Bottom step enlarging horizontal momentum flux of dam break flow. Ocean Engineering, 214, p.107729.
Song, Y., Guo, X., Wang, H., Tian, X., Wei, H. and Zhang, X.*, 2020. Performance analysis of an adaptive bistable point absorber wave energy converter under white noise wave excitation. IEEE Transactions on Sustainable Energy, 12(2), pp.1090-1099.
2019年度
Zhang, X.*, Zheng, S., Lu, D. and Tian, X., 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.
Lu, D., Tian, X., Lu, W. and Zhang, X.*, 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.
Zhang, X.*, Draper, S., Wolgamot, H., Zhao, W. and Cheng, L., 2019. Eliciting features of 2D greenwater overtopping of a fixed box using modified dam break models. Applied Ocean Research, 84, pp.74-91.
Zhang, X., Tian, X., Xiao, L., Li, X. and Lu, W.*, 2019. Mechanism and sensitivity for broadband energy harvesting of an adaptive bistable point absorber wave energy converter. Energy, 188, p.115984.
2018年以前
Zhang, X.*, Tian, X., Xiao, L., Li, X. and Chen, L., 2018. Application of an adaptive bistable power capture mechanism to a point absorber wave energy converter. Applied Energy, 228, pp.450-467.
Zhang, X., Lu, D., Gao, Y. and Chen, L., 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.
Zhang, X. and Lu, D.*, 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.
Sun, Y., Lu, D., Xu, J. and Zhang, X.*, 2018. A study of hydroelastic behavior of hinged VLFS. International Journal of Naval Architecture and Ocean Engineering, 10(2), pp.170-179.
Zhang, X.*, Lu, D., Guo, F., Gao, Y. and Sun, Y., 2018. The maximum wave energy conversion by two interconnected floaters: Effects of structural flexibility. Applied Ocean Research, 71, pp.34-47.
Sun, Y. and Zhang, X.*, 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.
Zhang, X.T., Yang, J.M. and Xiao, L.F., 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.
Zhang, X., Yang, J.*, Zhao, W. and Xiao, L., 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).
Zhang, X.* and Yang, J., 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.
讲授课程:
《海洋可再生能源》,授课对象:本科生
《船舶与海洋工程导论》,授课对象:本科生
《Scientific Writing, Integrity and Ethics》,授课对象:研究生
《数字信号处理与工程应用》,授课对象:研究生
一种研究立柱-网衣结构耦合水动力特性的试验装置,2023.03.01,中国,(已授权,第一发明人)
一种随船浪高仪可伸缩式套筒标定装置,2022.02.11,中国,CN113418584A,(已授权,第一发明人)
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,CN109854434A,(授权,第一发明人)
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,CN103759872B (已授权)
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,CN102359854B(已授权)
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,CN102359856B (已授权)
全国船舶与海洋工程学科高等教育教学成果奖二等奖《船舶与海洋工程导论课教学改革与实践—“产出导向,团队学习,思政同行”》,排2/6,省部级
上海市一流本科课程《大型海洋平台结构与动力响应仿真平台》,2021年,排2/12,省部级
上海市重点建设课程《船舶与海洋工程导论》,2022年,排2/6,省部级
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
第二届海南省“优秀研究生导师团队”,核心成员(省部级)
2022年,澳门太阳网城官网聘期考核优秀
第33届水波与浮体国际研讨会Tuck Fellowship
2019年,上海市浦江人才计划
