National Science Foundation for Distinguished Young Scholars
National Science Foundation for Excellent Young Scholars
World's Top 2% Scientists (Stanford/Elsevier)
First level prize, Science & technology Development Award, China National Committee on Large Dams
First level prize, Science & technology Development Award, China Society for Oceanography
First level prize, Standard Science & technology Innovation Award, China Association for Engineering Construction Standardization
Fellow of The Institute of Civil Engineers
Fellow of The Institute of Marine Engineering, Science and Technology
Tsinghua University 8th Youth Faculty Teaching Competition 1st Class Prize
K.C. Wong Education Foundation Project Award
Preferential funding for overseas students supported by Ministry of Human Resources and Social Security of the People's Republic of China
Panel Co-chair, Maritime Engineering (ICE Journal)
Editorial Board Member, Structures (IStructE journal)
Chartered Engineer (UK Engineering Council, Reg. 587772)
Project Management Professional (Project Management Institute, Reg. 1780709)
Fellow of The Institute of Marine Engineering, Science and Technology (FIMarEST, Reg. 8012123)
Fellow of The Institute of Civil Engineer (FICE, Reg. 64589972)
Member, CSSD
Deputy General Secretary, CSO Deep Sea Technology Branch
Member, CSO Technology Equipment Professional Committee
Member, CSCS Ocean Steel Structure Branch
Selected Projects:
Structural Calculation Theory and Optimal Adjustment Method of Composite Submarine Pipeline, funded by National Natural Science Foundation of China, PI.
Subsea Pipeline Structures, funded by National Natural Science Foundation of China, PI.
Investigation on mechanism and design of concrete-filled double steel skin composite pipeline subjected to underwater explosion loading, funded by National Natural Science Foundation of China, PI.
Investigations on mechanism and design of carbon steel-concrete-stainless steel composite submarine pipeline under compression-bending-torsion and fatigue loadings, funded by National Natural Science Foundation of China, PI.
The application of Concrete-filled Double Skin Structures on Costal Construction, funded by National Key Research and Development Plan, PI.
Investigations on post fire assessment method and fire resistance performance of special building structures, funded by National Key Research and Development Plan, PI.
Development of real-time offshore pipeline installation monitoring system for pipelay vessel HYSY 201, funded by China National Offshore Oil Corporation Research Project, PI
Subsea in-line manifold installation key technology, funded by China National Offshore Oil Corporation Research Project, PI
Standard (Selective)
[1]China Association for Engineering Construction Standardization Standard, Technical specification for Concrete-filled Double Skin Steel Subsea Pipeline. (In Chinese)
[2]National Standard, General rules for building protection. (In Chinese)
[3]National Standard, Technical standard for concrete-filled steel tubular hybrid structures, GB/T 51446 (In Chinese & English )
[4]China Civil Engineering Society Standard, Technical Specification for concrete-Filled double skin steel tubular structures, T/CCES 7. (In Chinese)
[5]China National Offshore Oil Corporation - Company standard, Guideline for analysis of subsea pipeline with in-line structure installation, Q/HS 3066. (In Chinese)
Patent (Selective)
[1]Utility patent, Carbon steel-concrete/cement mortar-stainless steel composite submarine pipeline, 17/257,174, USA.
[2]Utility patent. Real-time analysis system for operation of working ship based on ship attitude measurement, 15/765491, USA.
[3]Invention patent, CFDST pile and its construction method. ZL202111536797.3, China
[4]Patent for utility model, Experimental equipment and method of the bond behavior of CFST structure, ZL202110823953.8, China.
[5]Testing equipment and method for Stress-Corrosion behavior of steel material under coupled alternate immersion and sustainable loading conditions. ZL202110057346.5, China.
Journal papers and books (Selective)
[1]Wang F. Subsea Pipeline Design Manual [M]. Beijing: Tsinghua University Press, 2022.
[2]Wang F*, Li B, Cheng Z, et al. Coupling effect of freeze–thaw cycles and multiaxial compression on concrete-filled steel tube (CFST): Insights from simplified meso-scale axisymmetric finite element model[J]. Engineering Structures, 2023, 280: 115691.
[3]Wang F*, Cheng Z, Shen J. Flexural fatigue behavior of butt-welded circular concrete-filled double skin steel tube (CFDST):Experimental study and numerical modeling[J]. Marine Structures, 2023, 88: 103380.
[4]Cheng Z, Wang F*, Zhang D. Analytical model for axially compressed circular concrete-filled double skin steel tubes (CFDSTs): Insights from concrete non-uniformly confined states[J]. Thin-Walled Structures, 2023, 192: 111106.
[5]Wang F*, Cheng Z, Li B. Confinement-dependent failure criterion for high-strength concrete in multiaxial stress states[J]. Construction and Building Materials, 2023, 366: 130164.
[6]Lin L, Wang F*. Investigation of analytical behavior of concrete filled steel tubular (CFST) offshore rock-socketed pile under lateral load[J]. Ocean Engineering, 2023, 277: 114279.
[7]Wang F*, Li S. Numerical investigation of concrete-filled double skin steel tubular (CFDST) structure subjected to underwater explosion loading[J]. Marine Structures, 2023, 90: 103427.
[8]Zhu Z, Yang L, Wang F*, Gang Y. Testing, simulation, and design for analyzing the behavior of lined pipes under torsion [J]. Ocean Engineering, 2023, 286: 115708.
[9]Bu Y, Yang L, Zhu Z, Wang F*. Testing, simulation and design of offshore lined pipes under axial compression[J]. Marine Structures, 2022, 82: 103147.
[10]Wang F*, Xie W, Li B, Han L. Experimental study and design of bond behavior in concrete-filled steel tubes (CFST)[J]. Engineering Structures, 2022, 268: 114750.
[11]Wang J, Wang F*. Analytical behavior of built-up square concrete-filled steel tubular columns under combined preload and axial compression[J]. Steel and Composite Structures, 2021, 38(6): 617-635.
[12]Bu Y, Yang L, Zhu Z, Wang F*. Flexural buckling behaviour and design of offshore lined pipes under compression[J]. Ocean Engineering, 2020, 214: 107829.
[13]Wang F*, Zhao H. Experimental investigation on blast furnace slag aggregate concrete filled double skin tubular (CFDST) stub columns under sustained loading[J]. Structures, 2020, 27: 352-360.
[14]Wang F*, Han L. Analytical behavior of carbon steel-concrete-stainless steel double-skin tube (DST) used in submarine pipeline structure[J]. Marine Structures, 2019, 63: 99-116.
[15]Wang F*, Li W, Han L. Interaction behavior between outer pipe and liner within offshore lined pipeline under axial compression[J]. Ocean Engineering, 2019, 175: 103-112.
[16]Wang F*, Zhao H, Han L. Analytical behavior of concrete-filled aluminum tubular stub columns under axial compression[J]. Thin-Walled Structures, 2019, 140: 21-30.
[17]Wang F*. Effective design of submarine pipe-in-pipe using Finite Element Analysis[J]. Ocean Engineering, 2018, 153: 23-32.
[18]Wang F*, Han L. Analytical behavior of special-shaped CFST stub columns under axial compression[J]. Thin-Walled Structures, 2018, 129: 404-417.
[19]Wang F*, Han L, Li W. Analytical behavior of CFDST stub columns with external stainless steel tubes under axial compression[J]. Thin-Walled Structures, 2018, 127: 756-768.
[20]Wang F*, Chen J, Gao S, et al. Development and sea trial of real-time offshore pipeline installation monitoring system[J]. Ocean Engineering, 2017, 146: 468-476.
Postgraduate and Post-doctor application are welcome.
Department of