基本信息

高福平: 中国科学院力学研究所,研究员;中国科学院大学工学院,岗位教授/博士生导师
电子邮件:fpgao@imech.ac.cn
通信地址:北京市海淀区北四环西路15号 
邮政编码:100190 

研究领域

学科方向海洋土力学;流固土耦合力学;海洋工程

试验技术:大型波流水槽的流固土耦合动力过程模拟;海洋工程流固土耦合多物理参数同步测试与实时监控

应用领域:海洋油气资源与可再生能源开发,主要包括海底管线与立管系统稳定性、海洋平台/水下生产系统结构基础承载力、近海风力和波浪发电结构基础系统设计分析等。 

招生信息

招生专业:工程力学  (方向:海洋工程力学/土动力学/流固土耦合)

欢迎工程力学、岩土力学与工程、水利/海洋工程、土木工程等专业背景的考生报考。

联系地址:中国科学院力学研究所 流固耦合系统力学重点实验室 100190
Email: fpgao@imech.ac.cn

教育背景

   
学历

1997-2001:中国科学院力学研究所,工程力学专业,博士研究生。

学位

2001年:获中国科学院力学研究所,理学博士学位。

工作经历

2003--至今: 中国科学院力学研究所, 先后聘为助理研究员、副研究员、研究员(博导)

2001--2002: 西澳大利亚大学/Griffith大学, 博士后

2000--2000: 香港科技大学, 访问学者

2015--2015:西澳大利亚大学,访问教授


主要社会兼职:

Ocean Engineering, Theoretical & Applied Mechanics Letters, Journal of Hydrodynamics, Journal of Marine Science and Application, 应用数学和力学、岩土工程学报等期刊编委。

中国力学学会理事、中国科学院力学研究所学术委员会委员;国际土力学与岩土工程学会(ISSMGE)第四届冲刷土工技术委员会副主任、海洋土力学专业委员会委员;国际海洋与极地工程学会(ISOPE)技术委员会委员(TPC Member);美国土木工程师学会ASCE 会员。

专利与奖励

发明专利:

    1) 钢悬链线立管与海床动力耦合模拟装置及方法 (专利号: ZL201310339182.0)

    2) 基于主动立体视觉技术的模拟海床地形测量方法及测量装置(专利号ZL 201310520389.8)

    3) 一种模拟斜坡海床的土体制备装置及方法(专利号:ZL201010277593.8) 

    4) 斜坡海床上管道在位稳定性的机械加载模拟装置及方法(专利号:ZL201010281525.9) 

    5) 波流-结构物-海床动力耦合实验模拟方法及其装置 (专利号:ZL2004100336343) 

    6) 用鼓型离心机模拟海浪的方法及其装置 (专利号:ZL03148718.1)

    7) 检测海底直铺管道侧向稳定性的模拟方法及其模拟装置 (专利号:ZL200810056643.2) 

    8) 渗透变形诱导海底管道地基悬空的模拟方法及装置 (专利号:ZL2005101029953) 


主要奖励:
    1) 2012年:入选中国科学院青年创新促进会   

    2) 2011年:获中国力学学会青年科技奖

    3) 2009年:获中国科学院卢嘉锡青年人才奖

    4) 2007年:入选北京市科技新星计划

        2014-2015连续两年,入选爱思维尔(Elsevier)发布的中国高被引学者榜单:海洋工程领域

出版信息

共发表学术论文110余篇,其中SCI收录34篇、EI收录55篇。代表性论文:

1.       Gao, F.P., Wang,N., Li, J. H., Han, X.T. (2016): Pipe-soil interaction model for current-induced pipeline instability on a sloping sandy seabed. Canadian Geotechnical Journal, 2016 (In press)

2.       Qi, W.G., Gao, F.P., Randolph, M.F., Lehane, B.M. (2016): Scour effects on p–y curves for shallowly embedded piles in sand. Géotechnique, 66(8): 648-660. (SCI/EI)

3.       Gao, F.P.Li, J.H., Qi, W.G., Hu, C. (2015): On the instability of offshore foundations: theory and mechanism. Science China-Physics, Mechanics & Astronomy, 2015, 58 (12): 124701. (SCI/EI)

4.       Gao, F.P., Wang, N., Zhao, B. (2015): A general slip-line field solution for the ultimate bearing capacity of a pipeline on drained soils. Ocean Engineering, 2015, 104: 405-413. (SCI/EI)

5.       Gao, F.P., Cassidy, M. (2015): Editorial: Special issue on offshore structure-soil interaction. Theoretical and Applied Mechanics Letters, 2015, 5: 63.

6.       Hu, C., Gao, F.P. (2015). Elasto-plasticity and pore-pressure coupled analysis on the pullout behaviors of a plate anchor. Theoretical and Applied Mechanics Letters, 2015, 5: 89-92.

7.       Qi, W G, Gao, F.P. (2015): A modified criterion for wave-induced momentary liquefaction of sandy seabed. Theoretical and Applied Mechanics Letters, 2015, 5: 20-23.

8.       Qi, W G, Gao, F.P. (2014): Equilibrium scour depth at offshore monopile foundation in combined waves and current. Science China, Technological Sciences, 2014, 57(5): 1030-1039. (SCI/EI)

9.       Qi, W.G. and Gao, F.P. (2014): Physical modeling of local scour development around a large-diameter monopile in combined waves and current. Coastal Engineering, 2014, 83: 72-81. (SCI/EI)

10.    Zang, Z.P., Gao, F.P. (2014): Steady current induced vibration of near-bed piggyback pipelines: Configuration effects on VIV suppression. Applied Ocean Research, 2014, 46: 62-69. (SCI/EI)

11.    Wang, Y.F., Gao, F.P., Qi, W.G. (2014): Cyclic pore pressure generation in silty soils under the action of combined waves and current. Geotechnical Engineering Journal, 2014, 45(4): 40-45. (EI)

12.    Gao, F.P.Wang, N., Zhao, B. (2013): Ultimate bearing capacity of a pipeline on clayey soils: Slip-line field solution and FEM simulation. Ocean Engineering, 2013, 73: 159-167. (SCI/EI)

13.    Zang, Z.P., Gao, F.P., Cui, J.S. (2013): Physical modeling and swirling strength analysis of vortex shedding from near-bed piggyback pipelines. Applied Ocean Research, 2013, 40: 5059. (SCI/EI)

14.    Zhang, Y., Jeng, D.-S., Gao, F.P., Zhang, J.-S. (2013): An analytical solution for response of a porous seabed to combined wave and current loading. Ocean Engineering, 2013, 57: 240–247. (SCI/EI)

15.    Gao, F.P. & Zhao, B. (2012): Slip-line field solution for ultimate bearing capacity of a pipeline on clayey soils. Theoretical & Applied Mechanics Letters, 2012, 2: 051004.

16.    Gao, F.P., Han, X.T., Cao, J., Sha, Y., Cui, J.S. (2012): Submarine pipeline lateral instability on a sloping sandy seabed. Ocean Engineering, 2012, 50: 4452. (SCI/EI)

17.    Gao, F.P., Han, X.T., Yan, S.M. (2012): A numerical model for ultimate soil resistance to an untrenched pipeline under ocean currents. China Ocean Engineering, 2012, 26(2): 185194. (SCI/EI)

18.    Gao, F.P., Yan, S.M., Yang, B., Luo, C.C. (2011): Steady flow-induced instability of a partially embedded pipeline: Pipe–soil interaction mechanism. Ocean Engineering, 2011, 38: 934942. (SCI/EI)

19.    Li, X.J., Gao, F.P., Yang, B., Zang, J. (2011): Wave-induced pore pressure responses and soil liquefaction around pile foundation. International Journal of Offshore and Polar Engineering, 2011, 21(3): 233239. (SCI/EI)

20.    Hong Y.S., Mazzolani F. M., Gao, F.P. (2010): ISAB-2010 Foreword. Procedia Engineering, 2010, 4:12. (EI)

21.    Yan, W.J. & Gao, F.P. (2010): Numerical analysis of interfacial shear degradation effects on axial uplift bearing capacity of a tension pile. Procedia Engineering, 2010, 4: 273281. (EI)

22.    Gao, F.P. & Luo, C.C. (2010): Flow-Pipe-Seepage Coupling Analysis on Spanning Initiation of a Partially-Embedded Pipeline. Journal of Hydrodynamics, 2010, 22(4): 478487. (SCI)

23.    Zhao, C.G., Liu, Y., Gao F.P. (2010): Work and energy equations and the principle of generalized effective stress for unsaturated soils. International Journal for Numerical and Analytical Method in Geomechanics, 2010; 34: 920–936. (SCI, EI)

24.    Jeng, D.S., Zhou, X.L., Luo, X.D., Wang, J.H., Zhang, J. and Gao, F. P. (2010): Response of Porous Seabed to Dynamic Loadings. Geotechnical Engineering Journal of SEAGS & AGSSEA, 41(4): 1-10. EI

25.    Yang, B., Gao, F. P., Li, D.H., Wu, Y. X. (2009): Physical modelling and parametric study on two-degree-of-freedom VIV of a cylinder near rigid wall. China Ocean Engineering, 2009, 23(1): 119132. (SCI, EI)

26.    Yang, B., Gao, F. P., Jeng, D.S., Wu, Y. X. (2009): Experimental study of vortex-induced vibrations of a cylinder near a rigid plane boundary in steady flow. Acta Mechanica Sinica, 25: 5163. (SCI, EI)

27.    Yang, B., Jeng, D.S., Gao, F. P., Wu, Y. X. (2008). Forces Acting on the Seabed around a Pipeline in Unidirectional Ocean Currents. The Open Civil Engineering Journal, 2: 148155.

28.    Yang, B., Gao, F. P., Wu, Y. X. (2008): Flow-induced vibrations of a cylinder with two degrees of freedom near rigid plane boundary. International Journal of Offshore and Polar Engineering, 18 (4): 302307. (SCI, EI)

29.    Yang, B., Gao, F. P., Jeng, D.S., Wu, Y. X. (2008): Experimental study of vortex-induced vibrations of a pipeline near an erodible sandy seabed. Ocean Engineering, 35: 301309. (SCI, EI)

30.    Gao, F. P., Yan, S.M., Yang, B., Wu, Y. X. (2007): Ocean currents-induced pipeline lateral stability. Journal of Engineering Mechanics, ASCE, 133(10): 10861092. (SCI, EI)

31.    Jeng, D.S., Seymour, B., Gao, F.P., Wu, Y.X. (2007): Ocean waves propagating over a porous seabed: residual and oscillatory mechanisms. Science in China, Series E Technological Sciences, 50(1): 8189. (SCI, EI)

32.    Gao, F. P., Yang, B., Wu, Y. X., Yan, S.M. (2006): Steady currents induced seabed scour around a vibrating pipeline. Applied Ocean Research, 28: 291298. (SCI, EI)

33.    Gao, F. P., Jeng, D. S., Wu, Y. X (2006): An Improved Analysis Method for Wave-Induced Pipeline Stability on Sandy Seabed. Journal of Transportation Engineering, ASCE, 132(7): 590596 (SCI, EI)

34.    Yang, B., Gao, F.P., Wu, Y.X.(2006): Dimensional Analysis and Experimental Apparatus on Interaction between Ocean Current-Pipeline and Seabed. Journal of Ship Mechanics, 10(3): 130141 (EI)

35.    Zhao, C.G., Dong, J., Gao, F.P. (2006). An Analytical Solution for Three-Dimensional Diffraction of Plane P-Waves by a Hemispherical Alluvial Valley with Saturated Soil Deposits. Acta Mechanica Solida Sinica,19(2):141151 (SCI, EI)

36.    Yang, B., Gao, F. P., Wu, Y.X., Li, D.H. (2006): Experimental Study on Vortex-Induced Vibrations of Submarine Pipeline Near Seabed Boundary in Ocean Currents. China Ocean Engineering, 2006, 20(1):113121 (SCI, EI)

37.    Zhao, C.G., Dong, J., Gao, F.P., Jeng, D.S. (2006): Seismic responses of a hemispherical alluvial valley subjected to SV waves: A three-dimensional analytical approximation. Acta Mechanica Sinica, 22(6): 547557. (SCI, EI)

38.    Gao, F. P., Wu, Y. X. (2006): Non-linear Wave Induced Transient Response of Soil around a Trenched Pipeline. Ocean Engineering, 33: 311330 (SCI, EI)

39.    Zhao C.G., Yang Z.M., Gao F.P. and Zhang Y.N. (2005). Influential Factors of Loess Liquefaction and Pore Pressure Development. Acta Mechanica Sinica, 21(2): 129132. (SCI, EI)

40.    Gao, F. P., Jeng, D. S. and Sekiguchi, H. (2003): Numerical Study on the Interaction between Non-Linear Wave, Buried Pipeline and Non-Homogenous Porous Seabed. Computers and Geotechnics, 30:535547. (SCI, EI)

41.    Gao, F. P., Gu, X. Y. and Jeng, D. S. 2003: Physical Modeling of Untrenched Submarine Pipeline Instability. Ocean Engineering, 30 (10): 12831304.(SCI, EI)

42.    Gao, F. P., Gu, X. Y., Jeng, D. S. and Teo H.T. (2002): An Experimental Study for Wave-Induced Instability of Pipelines: The Breakout of Pipelines. Applied Ocean Research, 24: 8390. (SCI, EI)

43.    Jeng, D. S., Gao, F. P. and Sekiguchi, H. (2002): Effects of Wave Non-Linearity on the Wave-Induced Responses of Soil and Buried Pipeline: Application of GFEM-WSSI. Journal of Engineering, 13(2): 7790.

44.    Gu, X.Y., Gao, F.P. and Pu, Q. (2001): Wave-Soil-Pipe Coupling Effect upon Submarine Pipeline On-Bottom Stability. Acta Mechanica Sinica, 17(1): 8696. (SCI, EI).

45.    Pu, Q., Li, K., Gao F.P (2001): Scour of the Seabed under a Pipeline in Oscillating Flow. China Ocean Engineering, 15(1)129137. (SCI, EI).


科研活动

近期开展的主要科研项目:

1.国家重点基础研究发展计划(973计划)项目:大型风力机的关键力学问题研究及设计实现(2014-2018),课题:海上固定式风力机支撑结构与基础的动力特性与安全性研究,主要参加人

2.国家自然科学基金面上项目深海管道在位稳定性的流固土耦合机理及分析方法研究(2014-2017),项目负责人

3.国家自然科学基金重点项目极端海洋环境下风机支撑结构耦合载荷与动力响应机理研究(20132017)主要参加人

4.国家自然科学基金面上项目:海洋平台地基极限平衡冲刷深度预测(2009-2011),项目负责人

5.中海石油(中国)有限公司技术服务项目:南海某气田群开发工程砂脊砂波及路由海床稳定性研究(2013-2014),项目负责人

6.中国石油规划总院技术开发项目海底管线临界悬跨长度研究(2012-2013),项目负责人

7.华北电力设计院技术咨询项目:海上风电场风机基础设计研究(2012-2013),项目负责人

8.中国科学院科学事业单位修缮购置专项:海洋流固土耦合水槽模拟技术提升及高精度测量系统搭建(2012-2012),项目负责人

9.国家科技重大专项(大型油气田及煤层气开发)子课题:深水海底管道和立管检测技术研究(2008-2010),课题副组长

10.中澳天然气技术伙伴关系基金(AUSTRALIA– CHINA NATURAL GAS TECHNOLOGY PARTNERSHIP FUND):Geotechnical Solutions for Engineering Deep Water Gas Fields,(2011-2014),力学所方负责人



合作情况

与西澳大利亚大学等高校以及中海油、中石油等企业开展密切的合作研究。