ZHU Hai

Publisher:陈良蕾Time:2022-12-03Views:66

Photo

Name

Hai ZHU

Gender

Male

Date of Birth

1986.01

Position

Associate Professor

Graduated Institution

Hohai University

Major

Hydraulics and River Dynamics

Degree

Ph. D

Telephone   Number

13770507364

E-mail

h.zhu@hhu.edu.cn

Research Interests

1.   Numerical simulation of hydrodynamics and water environment for rivers and   lakes;

2.   Environmental hydraulics and density stratified flows;

3.   CFD technology

Awards & Honors

1.   Excellent instructor of the first National Water Science Numerical Simulation   Innovation Competition, 2020

2.   First prize of the Huaihe River Committee Science and Technology Award, 2017

3.   Second prize in the lecture competition (youth group) of Hohai University

Achievements

Hai Zhu*,   Shengjie LuLingling Wang, Jieru Xu and Saiyu Yuan.   Numerical Study of Mixing Process by Point Source Pollution with Different   Release Positions in a Sinuous Open Channel. Water 2022, 14(12), 1903.

Mao Songping, Zhu   Hai* and Lu Shengjie, etc. Numerical simulation of contaminants transport   at a typical flow confluence of the Yellow River, the 5th International   Symposium on Shallow Flows, October 23-25, 2021, Nanjing, China.

Lu Shengjie, Zhu Hai* and Mao Songping, etc.   Numerical study of scalar transport affected by point source position in   curved open channel, the 5th International Symposium on Shallow Flows,   October 23-25, 2021, Nanjing, China.

Zhang X, Wang L L, Zhu H, et al. Pore-scale Simulation   of Salt Fingers in Porous Media Using a Coupled Iterative Source-Correction   Immersed Boundary-Lattice Boltzmann Solver Applied Mathematical Modelling,   2021, 94(6).

Hai Zhu, Songping   Mao, Decai Sun, etc. Reynolds number effects of internal solitary waves   propagating on a uniform slope. Proceedings of the 22nd IAHR-APD Congress   2020, Sapporo, Japan. (BEST PAPER   AWARD).

Chengxiao Zhang, Lingling Wang, Hai Zhu, Hongwu Tang. Integrated   hydrodynamic model for simulation of river-lake-sluice interactions. Applied   Mathematical Modelling 83 (2020) 90-106.

Zhang X , Wang L L, Zhu H, et al. Modeling of salt finger   convection through a fluid-saturated porous interface: Representative   elementary volume scale simulation and effect of initial buoyancy ratio.   Physics of Fluids, 2020, 32(8):082109.

Hai Zhu, Lingling   Wang, Hongwu Tang, etc. Numerical Investigation of Sediment Transport Induced   by Internal Solitary Waves. 13th ICHE Proceeding, June 18-22, 2018,   Chongqing, China.

H. Zhu, C. Lin, L.   Wang, M. Kao, H. Tang, & Williams, J. J. R. (2018). Numerical   investigation of internal solitary waves of elevation type propagating on a   uniform slope. Physics of Fluids, 30(11)116602.

Lingling Wang, Jin Xu, Yin Wang,   Gang Wei, Chang Lin, Hai Zhu*.   Reduction of internal-solitary-wave-induced forces on a circular cylinder   with a splitter plate. Journal of Fluids and Structures 83 (2018) 119-132.

Xianfei Zhang, Ling-ling Wang,   Cheng Lin, Hai Zhu, and Cheng   Zeng. Numerical study on tilting salt finger in a laminar shear flow. Physics   of Fluids 30, 022110 (2018).

Pengjie Hu, Lingling Wang, Zhiwei   Li and Hai Zhu, etc. Numerical   Simulation of the Interaction between Phosphorus and Sediment Based on the   Modified Langmuir Equation. Water 2018, 10, 840.

H. Zhu, L. L. Wang,   E. J. Avital, H. W. Tang and J. J. R. Williams (2017). Numerical simulation   of shoaling broad-crested internal solitary waves. Journal of Hydraulic   Engineering, 143(6): 04017006.

Hai Zhu, Lingling   Wang, Hongwu Tang, Qunliang Yang and J.J.R Williams. An iterative Neumann   boundary condition method and its application in the simulation of breaking   internal solitary waves[C]. Proceedings of the 37th IAHR World Congress,   August 13 – 18, 2017, Kuala Lumpur, Malaysia. ISSN 1562-6865

H. Zhu, L. L. Wang,   E. J. Avital, H. W. Tang and J. J. R. Williams (2016), Numerical simulation   of interaction between internal solitary waves and submerged ridges. Applied   Ocean Research, 58: 118-134.

Yang Wang, Wei He, Hai Zhu. Computational fluid dynamics   (CFD) based modelling of osmotic energy generation using pressure retarded   osmosis (PRO) [J]Desalination2016389: 98-107.

Yin Wang, Lingling Wang*, Hai Zhu, Hongwu Tang, and Gang Wei. A   Numerical Study of the Forces on Two Tandem Cylinders Exerted by Internal   Solitary Waves [J]. Mathematical Problems in Engineering, 2016, Article ID:   9086246.

H. Zhu, L. L. Wang,   and H. W. Tang (2014). Large-eddy simulation of the generation and   propagation of internal solitary waves. Science China Physics, Mechanics   & Astronomy 57(6): 1128-1136.

H. Zhu, L. L. Wang   and H. W. Tang (2013). Large-eddy simulation of suspended sediment transport   in turbulent channel flow. Journal of Hydrodynamics, Ser. B, 25(1): 48-55.

Projects

1.   Multi-objective regulation model integration and platform construction of   river networks in the middle and lower reaches of the Yangtze River Plain, Special   topic of National key Research and Development Project

2.   Multi-agent benefit compensation accounting method for water and sediment   control in river basin system with multi-function coordination, Special topic   of National key Research and Development Project

3.   Study on sediment pollution characteristics and basement remediation   technology of deep water reservoir, Special topic of National key Research   and Development Project

4.   Large eddy simulation of offshore dynamic processes of isolated waves in real   scale, National Natural Science Foundation of China Youth Foundation

5.   Numerical study of shallow water dynamic characteristics of isolated waves in   real scale, China Postdoctoral Science Foundation

6.   Huaihe river main stream pollution cluster evolution research, science and   technology consulting project

7.   Large eddy simulation of water environment in typical reaches of Yellow River   Basin, science and technology consulting project

Personal Website

https://www.researchgate.net/profile/Hai-Zhu-19

http://yjss.hhu.edu.cn/dsfc/dsfcgrxx/8203FA34A10A90667BF2E88D0066E3D4