何涛

发布单位:人员机构编辑:发布日期:2019/09/23浏览量:5521

基本信息

姓名:何涛
性别:

学位职称:博士
/副研究员/硕士生导师
联系地址:上海市海思路
100
邮政编码:
201418
办公电话:
021-57124068
电子信箱:
taohe@shnu.edu.cn


研究兴趣

流固耦合有限元方法计算流体力学

教育背景

2014.07-2018.06,英国伯明翰大学/土木工程/哲学博士
2008.09-2013.12
上海交通大学
/结构工程/工学博士
2004.09-2006.12
华中科技大学
/结构工程/工学硕士
2000.09-2004.06
武汉科技大学
/土木工程/工学学士

工作经历

2016.09至今,上海师范大学/建筑工程学院/研究员(破格晋升)
2017.08-2018.07
爱丁堡龙比亚大学
/工程与建筑环境学院/访问学者
2014.12-2016.08
上海师范大学
/ok138cn太阳集团/
2007.04-2008.06
中国地震局
/地震研究所/理工程师

主持项目

[04]  上海市自然科学基金面上项目:基于特征线分裂的流固耦合分区半隐式算法研究及应用(19ZR14372002019.07-2022.06
[03]  
国家自然科学基金青年项目:风敏感结构流固耦合计算新方法与风致振动机理研究(
515083322016.01-2018.12
[02]  
上海高校青年教师培养资助计划:基于
ALE-CBS有限元技术的流固耦合分区算法研究ZZssd150912016.09-2018.08
[01]  
中国地震局地震研究所所长基金:竖向地震动对高耸结构的性能影响研究(
IS2007560492007.09-2008.06

荣誉与奖励

Editors PickPhysics of Fluids2020
Managing-Editor-Featured Paper
International Journal of Applied Mechanics2015
伯明翰大学
PGTA博士奖学金,2014
博士研究生国家奖学金,
2013
首届全国空间结构博士生学术论坛优秀论文奖,
2012
赵朱木兰奖学金,
2012
上海交通大学第四期博士生论坛优秀报告奖,
2011
光华奖学金,
2010

教学工作

研究生课程:《计算结构力学》、《专业英语》、《学术规范与论文指导》、《有限元与变分原理》
本科生课程:《土木工程测量》、《力学与生活》、《工程数学》
前沿技术讲座:《工程中的流固耦合—现象、原理与数值模拟》
夜大课程:《特种结构》

人才培养

指导研究生获得:高水平地方高校建设一流研究生教育项目、国家奖学金、一等/二等学业奖学金和上海市优秀毕业生
指导本科生获得:国家级/上海市级大创项目和校优秀实习毕业生

代表性论文

[34]  He T. CBS-based partitioned semi-implicit coupling algorithms for fluid-structure interaction: A decade review. Archives of Computational Methods in Engineering 2023; DOI: 10.1007/s11831-023-10029-8. (accepted as is)

[33]  He T*, Ma X. An edge-based smoothed finite element method for semi-implicit coupling of unsteady viscoelastic fluid-structure interaction. Computers and Structures 2023; 281: 107028.
[32]  
He T*, Yao WJ, Zhang XY. An edge-based smoothed finite element framework for partitioned simulation of vortex-induced vibration problems. International Journal for Numerical Methods in Fluids 2022; 94(11): 1863-1887.
[31]  
He T*, Zhang XY, Yao WJ. An edge-based smoothed finite-element method for vortex-induced vibration in generalized Newtonian fluids. Journal of Engineering Mechanics 2022; 148(11): 04022069.
[30]  He T. Modeling fluid-structure interaction with the edge-based smoothed finite element method. Journal of Computational Physics 2022; 460: 111171.
[29]  
He T. A stabilized cell-based smoothed finite element method against severe mesh distortion in non-Newtonian fluid-structure interaction. International Journal for Numerical Methods in Engineering 2022; 123(9): 2162-2184.
[28]  He T. On the edge-based smoothed finite element approximation of viscoelastic fluid flows. International Journal for Numerical Methods in Fluids 2022; 94(5): 423-442.
[27]  He T. Cell-based smoothed finite-element framework for strongly coupled non-Newtonian fluid-structure interaction. Journal of Engineering Mechanics 2021; 147(10): 04021062.
[26]  
He T. Stabilization of a smoothed finite element semi-implicit coupling scheme for viscoelastic fluid-structure interaction. Journal of Non-Newtonian Fluid Mechanics 2021; 292: 104545.
[25]  
He T. Extending the cell-based smoothed finite element method into strongly coupled fluid-thermal-structure interaction. International Journal for Numerical Methods in Fluids 2021; 93(4): 1269-1291.
[24]  
He T. Cell-based smoothed finite element method for simulating vortex-induced vibration of multiple bluff bodies. Journal of Fluids and Structures 2020; 98: 103140.
[23]  
He T. An efficient selective cell-based smoothed finite element approach to fluid-structure interaction. Physics of Fluids 2020; 32(6): 067102. (Editor's Pick)
[22]  
He T. A truly mesh-distortion-enabled implementation of cell-based smoothed finite element method for incompressible fluid flows with fixed and moving boundaries. International Journal for Numerical Methods in Engineering 2020; 121(14): 3227-3248.
[21]  
He T. A strongly-coupled cell-based smoothed finite element solver for unsteady viscoelastic fluid-structure interaction. Computers and Structures 2020; 235: 106264.
[20]  
He T. A cell-based smoothed CBS finite element formulation for computing the Oldroyd-B fluid flow. Journal of Non-Newtonian Fluid Mechanics 2019; 272: 104162.
[19]  
He T. The cell-based smoothed finite element method for viscoelastic fluid flows using fractional-step schemes. Computers and Structures 2019; 222: 133-147.
[18]  
He T, Wang T*. A three-field smoothed formulation for partitioned fluid-structure interaction via nonlinear block-Gauss-Seidel procedure. Numerical Heat Transfer, Part B: Fundamentals 2019; 75(3): 198-216. (accepted as is)
[17]  
He T. Insight into the cell-based smoothed finite element method for convection-dominated flows. Computers and Structures 2019; 212: 215-224.
[16]  
He T*, Zhang HX, Zhang K. A smoothed finite element approach for computational fluid dynamics: applications to incompressible flows and fluid-structure interaction. Computational Mechanics 2018; 62(5): 1037-1057.
[15]  
He T. A three-field smoothed formulation for prediction of large-displacement fluid-structure interaction problems via the Explicit Relaxed Interface Coupling (ERIC) scheme. Communications in Computational Physics 2018; 24(3): 742-763.
[14]  
He T*, Yang J, Baniotopoulos C. Improving the CBS-based partitioned semi-implicit coupling algorithm for fluid-structure interaction. International Journal for Numerical Methods in Fluids 2018; 87(9): 463-486.
[13]  
He T. Towards straightforward use of cell-based smoothed finite element method in fluid-structure interaction. Ocean Engineering 2018; 157: 350-363.
[12]  
He T*, Wang T, Zhang HX. The use of artificial compressibility to improve partitioned semi-implicit FSI coupling within the classical Chorin-Témam projection framework. Computers and Fluids 2018; 166: 64-77.
[11]  
He T*, Zhang K. An overview of the combined interface boundary condition method for fluid-structure interaction. Archives of Computational Methods in Engineering 2017; 24(4): 891-934.
[10]  
He T, Zhang K, Wang T*. AC-CBS-based partitioned semi-implicit coupling algorithm for fluid-structure interaction using stabilized second-order pressure scheme. Communications in Computational Physics 2017; 21(5): 1449-1474.
[09]  Wang T,
He T*, Li HJ. Effects of deformation of elastic constraints on free vibration characteristics of cantilever Bernoulli-Euler beams. Structural Engineering and Mechanics 2016; 59(6): 1139-1153.
[08]  
He T. A CBS-based partitioned semi-implicit coupling scheme for fluid-structure interaction using MCIBC method. Computer Methods in Applied Mechanics and Engineering 2016; 298: 252-278.
[07]  
He T*, Zhang K. Combined interface boundary condition method for fluid-structure interaction: Some improvements and extensions. Ocean Engineering 2015; 109: 243-255.
[06]  
He T. Semi-implicit coupling of CS-FEM and FEM for the interaction between a geometrically nonlinear solid and an incompressible fluid. International Journal of Computational Methods 2015; 12(5): 1550025.
[05]  
He T. On a partitioned strong coupling algorithm for modeling fluid-structure interaction. International Journal of Applied Mechanics 2015; 7(2): 1550021. (Managing-Editor-Featured Paper)
[04]  
He T. Partitioned coupling strategies for fluid-structure interaction with large displacement: Explicit, implicit and semi-implicit schemes. Wind and Structures 2015; 20(3): 423-448.
[03]  
He T. A partitioned implicit coupling strategy for incompressible flow past an oscillating cylinder. International Journal of Computational Methods 2015; 12(2): 1550012.
[02]  
He T, Zhou D*, Han ZL, Tu JH, Ma J. Partitioned subiterative coupling schemes for aeroelasticity using combined interface boundary condition method. International Journal of Computational Fluid Dynamics 2014; 28(6-10): 272-300.
[01]  
He T, Zhou D*, Bao Y. Combined interface boundary condition method for fluid-rigid body interaction. Computer Methods in Applied Mechanics and Engineering 2012; 223-224: 81-102.

学术服务

受邀为以下SCI期刊审稿人: 

Journal of Fluid Mechanics, Computer Methods in Applied Mechanics and Engineering, International Journal for Numerical Methods in Engineering, International Journal for Numerical Methods in Fluids, Journal of Non-Newtonian Fluid Mechanics, Computers and Fluids, Journal of Fluids and Structures, Physics of Fluids, International Journal of Heat and Fluid Flow, Applied Mathematical Modelling, Mathematics and Computers in Simulation, Applied Mathematics and Computation, Computers and Mathematics with Applications, International Journal of Mechanical Sciences, Acta Mechanica, Journal of Engineering Mechanics, Ocean Engineering, Archive of Applied Mechanics, International Communications in Heat and Mass Transfer, Computer Methods in Biomechanics and Biomedical Engineering, Engineering Computations, Engineering Analysis with Boundary Elements, Computer Modeling in Engineering & Sciences, Communications in Computational Physics, Structural Engineering and Mechanics, International Journal of Applied Mechanics, Wind and Structures, Earthquakes and Structures, Chinese Journal of Aeronautics, Scientia Iranica, Ain Shams Engineering Journal

受邀为以下国际会议审稿人: 
[1]  Proceedings of the 7th International and 45th National Conference on Fluid Mechanics and Fluid Power (FMFP), IIT Bombay, India, 2018
[2]  Proceedings of the ASME 2016 35th International Conference on Ocean, Offshore and Arctic Engineering (OMAE 2016), Busan, Korea, 2016