陶龙宾部门：船舶工程学院

学科：船舶与海洋工程

职务：

职称：教授

指导
资格：博士生导师
硕士生导师
电话：**

传真：**

邮箱：longbin.tao@hrbeu.edu.cn

邮编：150001

地址：哈尔滨工程大学61号楼5070
个人简介
陶龙宾 ，教授/博导。曾任英国纽卡斯尔大学劳氏船级社海洋工程讲席教授 ，国际船模拖曳会议海洋工程专业委员会（ITTC）委员，国际船舶与海洋结构物专业委员会（ISSC）委员等。现任英国劳氏船级社技术委员会委员，ASME海洋力学与极地工程学会（OMAE）海洋工程技术委员会委员。2009年被聘为上海交通大学船建学院讲座教授，2014年被聘为哈尔滨工程大学教授。

教育经历
2002年9月，西澳大利亚大学，海洋工程专业，获博士学位
1985年-1988年，华南理工大学，船舶与海洋工程专业，获硕士学位
1981年-1985年，华南理工大学，船舶与海洋工程专业，获学士学位




工作经历
2014年至今，哈尔滨工程大学，船舶工程学院，教授
2017年10月，英国斯特莱斯克莱德大学，船舶与海洋工程学院，教授
2009年1月至2017年9月，英国纽卡斯尔大学，劳氏船级社海洋工程讲席教授
2014年6月至今，上海交通大学，船建学院，访问讲座教授
2005年1月至6月，法国中央工学院（马赛），访问教授
2001年9月至2008年12月，澳大利亚格里菲斯大学，讲师、高级讲师
1988年8月至1997年4月，分别就任于广州海事局及澳大利亚造船厂




研究方向
[1] Numerical & Experimental Modelling of Hydrodynamics for Ship & Offshore Structures 船舶与海洋工程水动力学
[2] Wave Mechanics 波浪理论与应用
[3] Naval Architecture 船舶设计与制造[4] Subsea Production System 水下生产系统
[5] Computational Fluid Dynamics 计算流体动力学
[6] Offshore Renewable Energy 海洋可再生能源
[7] Coastal Hydrodynamics and Processes 近岸水动力学和过程
[8] Quantitative Assessment of Sustainability Development 可持续发展的量化分析
承担项目
Vortex-induced motions of the semi-submersibles
Reliability analysis and risk assessment of subsea production system
Scaled Boundary FEM for wave diffraction modelling of offshore structures
Vortex dynamics and effects on hydrodynamics of floating offshore structures
Nonlinear waves mechanics
Dynamics of offshore structures
Offshore Renewable Energy Systems


学术交流


招生信息
博士招生方向
- 船舶与海洋结构物设计制造

- 力学


硕士招生方向
- 船舶与海洋结构物设计制造

- 船舶与海洋工程



本科生授课课程
研究生授课课程
实践性教学
教学研究课题
社会兼职
Journal Editorial Board


1）2016年-至今，Marine Systems & Ocean Technology副主编。

2）2016年-至今，Journal of Ocean Engineering and Marine Energy副主编。
3）2014年-至今，ASCE Journal of Waterway, Port, Coastal and Ocean Engineering副主编。
4）2012年-至今，Journal of Marine Engineering and Technology (ImarEST)编委。
5）2011年-至今，Ocean Engineering编委。
6）2007年-2015年，ASME Journal of Offshore Mechanics and Arctic Engineering副主编。

Technical /Scientific Committee

1）2012年-至今，英国劳氏船级社技术委员会(TC)委员。

2）2007年-至今，ASME海洋力学与极地工程学会（OMAE）海洋工程技术（Offshore Technology）委员会委员。
3）2010年-2017年，国际船模拖曳水池会议海洋工程专业委员会(ITTC)委员。
4）2009年-2017年，国际船舶与海洋结构物专业委员会(ISSC)委员。








专利成果



出版著作


发表论文
[1] X.Y. Cao, L. Tao, A.M. Zhang, F.R. Ming, (2019): Smoothed particle hydrodynamics (SPH) model for coupled analysis of a damaged ship with internal sloshing in beam seas, Physics of Fluids, 31 (3) **.
[2] Yufeng Kou, Longfei Xiao, Longbin Tao and Tao Peng: Performance characteristics of a conceptual ring-shaped spar-type VLFS with double-layered perforated-wall breakwater, Applied Ocean Research, 2019, 86, 28-39.
[3] S. Gao, L. Tao, X. Tian and J. Yang, Flow around an inclined circular disk. Journal of Fluid Mechanics, 2018, 851: 687-714.
[4] M. Nuernberg and L. Tao, Experimental study of wake characteristics in tidal turbine arrays. Renewable Energy, 2018, 127: 168-181.
[5] Q. Zhao, H. Xu and L. Tao, Nanofluid flow and heat transfer in a microchannel with interfacial electrokinetic effects. International Journal of Heat and Mass Transfer, 2018, 124: 158-167.
[6] X. Cao, F. Ming, A. Zhang and L. Tao, Multi-phase SPH modelling of air effect on the dynamic flooding of a damaged cabin. Computers & Fluids, 2018, 163: 7-19.
[7] Shangmao Ai, Liping Sun, Longbin Tao: Modeling and Simulation of Deepwater Pipeline S-lay with Coupled Dynamic Positioning, Journal of Offshore Mechanics and Arctic Engineering, ASME, 2018, 140(5): 051701-051701-8.
[8] Martin Nuernberg and Longbin Tao: Three-dimensional tidal turbine array simulations using OpenFOAM with dynamic mesh, Ocean Engineering, 2018, 147, 629-646.
[9] M. Liu, L. Xiao, Y. Liang and L. Tao, Experimental and numerical studies of the pontoon effect on vortex-induced motions of deep-draft semi-submersibles. Journal of Fluids and Structures, 2017, 72: 59-79.
[10] X. Tian, L. Xiao, X. Zhang, J. Yang, L. Tao and D. Yang, Flow around an oscillating circular disk at low to moderate Reynolds numbers. Journal of Fluid Mechanics, 2017, 812: 1119-1145.
[11] Yibo Liang, Longbin Tao, Mingyue Liu, Longfei Xiao, (2016): Experimental and Numerical Study on Vortex-Induced-Motions of a Deep-Draft Semi-Submersible Concept, Applied Ocean Research, 67, 169-187.
[12] Yibo Liang and Longbin Tao (2017): Interaction of vortex shedding processes on the flow over a Deep-Draft Semi-Submersible, Ocean Engineering, 141, 427-449.
[13] Xinliang Tian, Longbin Tao, Xin Li, Jianmin Yang (2017): Hydrodynamic coefficients of oscillating flat plates at 0.15≤KC≤3.15, Journal of Marine Science and Technology.
[14] Torres-Lopez, J., Tao, L., Xiao, L. and Hu, Z. (2017): Experimental study on the hydrodynamic behaviour of a FPSO in a deepwater region of the Gulf of Mexico, Ocean Engineering, 129, 549-566.
[15] Longfei Xiao, Haining Lu, Longbin Tao, Lijun Yang (2017): LH-moment estimation for statistical analysis on the wave crest distributions of a deepwater spar platform, Marine Structures, 52, 15-33.
[16] I.A. Okaro and L. Tao, Reliability analysis and optimisation of subsea compression system facing operational covariate stresses. Reliability Engineering & System Safety, 2016, 156: 159-174.
[17] Z. Liu, Z. Lin and L. Tao, Nonlinear Wave–Current Interaction in Water of Finite Depth. Physics of Fluids, 2016, 28(12): 127104.
[18] L. Xiao, J. Yang, T. Peng and L. Tao, A free surface interpolation approach for rapid simulation of short waves in meshless numerical wave tank based on the radial basis function. Journal of Computational Physics, 2016, 307: 203-224.
[19] L. Xiao, H. Lu, X. Li and L. Tao, Probability analysis of wave run-ups and air gap response of a deepwater semi-submersible platform using LH-moments estimation method. Journal of Waterway, Port, Coastal and Ocean Engineering, 2016, 142(2): **.
[20] Qingkai Zhao, Hang Xu, Longbin Tao, A. Raees, Qiang Sun: Three-dimensional free bio-convection of nanofluid near the stagnation point on a general curved isothermal surface, Applied Mathematics and Mechanics, 2016, 37 (4), 417-432.
[21] Qingkai Zhao, Hang Xu, Longbin Tao: Homogeneous-heterogeneous reactions in boundary-layer flow of a nanofluid near the forward stagnation point of a cylinder, Journal of Heat Transfer, ASME, 2016, 139 (3) 034502.
[22] Lu, W., Yang, J.M., Tao, L.: Numerical study on the energy structure of the super-rogue waves, Ocean Engineering, 2016, 113, 295-307.
[23] Xiao, L.F., Kou, Y.F., Tao, L. and Yang, J.M.: A comparative study on hydrodynamic performance of double-layered perforated wall breakwaters attached to a ring-shaped VLFS, Ocean Engineering, 2016, 111, 279-291.
[24] L. Xiao, J. Yang, L. Tao and X. Li, Shallow water effects on high order statistics and probability distributions of wave run-ups along FPSO broadside. Marine Structures, 2015, 41: 1-19.
[25] W. Zhao, J. Yang, Z. Hu and L. Tao, Prediction of hydrodynamic performance of an FLNG system in side-by-side offloading operation. Journal of Fluids and Structures, 2014, 46: 89-110.
[26] Lin, Z., Tao, L., Pu, Y. and Murphy, AJ: Fully nonlinear solution of bi-chromatic deepwater waves, Ocean Engineering, 2014, 91, 290-299.
[27] Xiao, L.F., Tao, L., Yang, J.M. and Li, X.: An experimental investigation on wave run-up along the broadside of a single point moored FPSO exposed to oblique waves, Ocean Engineering, 2014, 88, 81-90.
[28] Zhao, W., Yang, J., Hu, Z. and Tao, L.: Coupled analysis of nonlinear sloshing and ship motions, Applied Ocean Research, 2014, 47, 85-97.
[29] Zhao, W., Yang, J., Hu, Z., Xiao, L. and Tao, L.: Hydrodynamics of a 2D vessel including internal sloshing flows, Ocean Engineering, 2014, 84, 45-53.
[30] Qiu, W., Junior, J., Lee, D. Lie, H., Magarovskii, V., Mikami, T., Rousset, J.M., Sphaier, S., Tao, L. and Wang, X.: Uncertainties related to predictions of loads and responses for ocean and offshore structures, Ocean Engineering, 2014, 86, 58-67.
[31] Zhao, W., Yang, J., Hu, Z. and Tao, L.: Coupling between roll motions of an FLNG vessel and internal sloshing, Journal of Offshore Mechanics and Arctic Engineering, ASME, 2014, 136(2).
[32] H. Song, L. Tao and S. Chakrabarti, Modelling of water wave interaction with multiple cylinders of arbitrary shape. Journal of Computational Physics, 2010, 229: 1498-1513.
[33] H. Song and L. Tao, An efficient scaled boundary FEM model for wave interaction with a nonuniform porous cylinder. International Journal for Numerical Methods in Fluids, 2010, 63: 96-118.
[34] Tao, Longbin, Song, Hao and Chakrabarti, S.K.: Scaled boundary FEM model for interaction of short-crested waves with a concentric porous cylindrical structure, Journal of Waterway, Port, Coastal and Ocean Engineering, ASCE, 2009, 135 (5), 200-212.
[35] L. Tao, H. Song and S. Chakrabarti, Wave interaction with a perforated circular breakwater of non-uniform porosity. Journal of Engineering Mathematics, 2009, 65: 257-271.
[36] L. Tao and D. Dray, Hydrodynamic performance of solid and porous heave plates. Ocean Engineering, 2008, 35: 1006-1014.
[37] L. Tao, B. Molin, Y. Scolan and K. Thiagarajan, Spacing effects of heave plates on hydrodynamics of offshore structures. Journal of Fluids and Structures, 2007, 23: 1119-1136.
[38] L. Tao, H. Song and S. Chakrabarti, Nonlinear progressive waves in water of finite depth—an analytic approximation. Coastal Engineering, 2007, 54: 825-834.
[39] L. Tao, H. Song and S. Chakrabarti, Scaled boundary FEM solution of short-crested wave diffraction by a vertical cylinder. Computer Methods in Applied Mechanics and Engineering, 2007, 197: 232-242.
[40] N. Cartwright, T.E. Baldock, P. Nielsen, D.S. Jeng and L. Tao, Swash‐aquifer interaction in the vicinity of the water table exit point on a sandy beach. Journal of Geophysical Research: Oceans, 2006, 111.
[41] Wu, X., Tao, L. and Li, Yuanlin: Nonlinear ship roll damping in regular and irregular waves. Journal of Offshore Mechanics and Arctic Engineering, ASME, 2005, 127 (3), 205-211.
[42] Tao, L. and Cai, S.: Heave motion suppression of a Spar with a heave plate. Ocean Engineering, 2004, 31 (5-6), 669-692.
[43] Tao, L., Lim K. Y. and Thiagarajan, K.: Heave response of a classic spar with variable geometry. Journal of Offshore Mechanics and Arctic Engineering, ASME, 2004, 126 (1), 90-95.
[44] L. Tao and K. Thiagarajan, Low KC flow regimes of oscillating sharp edges I. Vortex shedding observation. Applied ocean research, 2003, 25: 21-35.
[45] L. Tao and K. Thiagarajan, Low KC flow regimes of oscillating sharp edges. II. Hydrodynamic forces. Applied ocean research, 2003, 25: 53-62.
[46] Tao, L., Thiagarajan, K. and Cheng, L., On the parametric dependence of Springing Damping of TLP and Spar Columns. Applied Ocean Research, 2000, 22 (5), 281-294.

荣誉
2009年度教育部“****”奖励计划讲座教授

2017年 OMAE Conference Appreciation Award




奖励



自定义模块1



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