风浪荷载共同作用下的海洋桩基动力响应
收稿日期: 2019-08-20
网络出版日期: 2021-10-08
基金资助
国家自然科学基金(41572243);国家自然科学基金(41727802)
Dynamic Response of Marine Pile Foundation Under Combined Action of Wind and Wave Loads
Received date: 2019-08-20
Online published: 2021-10-08
为了研究海洋环境中风浪荷载共同作用下单桩基础的动力响应问题,建立了风浪-海床-单桩的三维单向耦合数值模型.分别采用雷诺平均N-S方程和Biot动力方程控制波浪运动和海床响应,在验证模型合理性的基础上,探究了风浪参数(如风速、风剪切系数、波高)对风浪荷载共同作用下流体与桩基响应的影响规律.结果表明:风速、风剪切系数和波高的增长会加剧桩周流体变形,加快波浪传播,进而影响桩身的水平位移与弯矩.因此,在计算海上桩基承载力时,应综合考虑风浪荷载共同作用对桩基基础的影响.研究成果将为恶劣海洋环境下桩基承载性能研究提供重要的理论依据.
李宛玲, 张琪, 周香莲 . 风浪荷载共同作用下的海洋桩基动力响应[J]. 上海交通大学学报, 2021 , 55(9) : 1116 -1125 . DOI: 10.16183/j.cnki.jsjtu.2019.246
In order to study the dynamic response of a single pile foundation under combined action of wind and wave loads in the marine environment, a three-dimensional unidirectional coupling numerical model of wind wave-seabed-single pile is established. The Reynolds average N-S equation and the Biot dynamic equation are used to control the wave motion and seabed response respectively. Based on the verification of the rationality of the model, the influence of wind and wave parameters (such as wind speed, wind shear coefficient, and wave height) on the response of fluid and pile foundation under combined action of wind and wave loads are explored. The results show that the increase of wind speed, wind shear coefficient, and wave height will aggravate the fluid deformation around the pile, accelerate the wave propagation, and then affect the horizontal displacement and bending moment of the pile. Therefore, when calculating the bearing capacity of offshore pile foundations, the combined effect of wind and wave loads on the pile foundation should be considered comprehensively. The results will provide an important theoretical basis for the study of the bearing performance of pile foundations in harsh marine environments.
| [1] | KEIVANPOUR S, RAMUDHIN A, AIT KADI D. The sustainable worldwide offshore wind energy potential: A systematic review[J]. Journal of Renewable and Sustainable Energy, 2017, 9(6):065902. |
| [2] | 李晓宇, 王伟. 基于SWOT分析我国海上风力发电的发展现状[J]. 华北电力大学学报(社会科学版), 2018(5):42-49. |
| [2] | LI Xiaoyu, WANG Wei. The status quo of China’s offshore wind power generation development based on SWOT analysis method[J]. Journal of North China Electric Power University (Social Sciences), 2018(5):42-49. |
| [3] | WANG P G, ZHAO M, DU X L, et al. Wind, wave and earthquake responses of offshore wind turbine on monopile foundation in clay[J]. Soil Dynamics and Earthquake Engineering, 2018, 113:47-57. |
| [4] | 马宏旺, 杨峻, 陈龙珠. 长期反复荷载作用对海上风电单桩基础的影响分析[J]. 振动与冲击, 2018, 37(2):121-126. |
| [4] | MA Hongwang, YANG Jun, CHEN Longzhu. Effects of long-term cyclic loadings on offshore wind turbine monopile foundation[J]. Journal of Vibration and Shock, 2018, 37(2):121-126. |
| [5] | KIM J H, KIM S, KIM D S, et al. Bearing capacity of hybrid suction foundation on sand with loading direction via centrifuge model test[J]. Japanese Geotechnical Society Special Publication, 2016, 2(37):1339-1342. |
| [6] | SHEMER L. Laboratory study of temporal and spatial evolution of waves excited on water surface initially at rest by impulsive wind forcing[J]. Procedia IUTAM, 2018, 26:153-161. |
| [7] | HRISTOV T. Mechanistic, empirical and numerical perspectives on wind-waves interaction[J]. Procedia IUTAM, 2018, 26:102-111. |
| [8] | BRUNETTI M, MARCHIANDO N, BERTI N, et al. Nonlinear fast growth of water waves under wind forcing[J]. Physics Letters A, 2014, 378(14/15):1025-1030. |
| [9] | PHILLIPS O M. On the generation of waves by turbulent wind[J]. Journal of Fluid Mechanics, 1957, 2(5):417. |
| [10] | LIU K, CHEN Q, HU K L, et al. Numerical simulations of sediment deposition and erosion on Louisiana Coast during hurricane Gustav[C]// The Proceedings of the Coastal Sediments 2015. California, USA: World Scientific, 2015: 1-14. |
| [11] | CHAMBAREL J, KHARIF C, KIMMOUN O. Ge-neration of two-dimensional steep water waves on finite depth with and without wind[J]. European Journal of Mechanics-B/Fluids, 2010, 29(2):132-142. |
| [12] | 张小玲, 刘建秀, 杜修力, 等. 风浪流共同作用下海上风电基础与海床的动力响应分析[J]. 防灾减灾工程学报, 2018, 38(4):658-668. |
| [12] | ZHANG Xiaoling, LIU Jianxiu, DU Xiuli, et al. Dynamic response analysis of offshore wind power foundation and seabed under the combined wind, wave and current loadings[J]. Journal of Disaster Prevention and Mitigation Engineering, 2018, 38(4):658-668. |
| [13] | 胡聪. 近海风电单桩基础所受波浪荷载计算方法研究[J]. 海洋技术学报, 2018, 37(5):89-94. |
| [13] | HU Cong. Study on the calculating methods of wave load acting on monopile supporting offshore wind turbines[J]. Journal of Ocean Technology, 2018, 37(5):89-94. |
| [14] | 张忆州, 廖晨聪, 陈锦剑. 椭圆余弦波作用下考虑桩身振动的桩-土相互作用[J]. 上海交通大学学报, 2019, 53(1):85-92. |
| [14] | ZHANG Yizhou, LIAO Chencong, CHEN Jinjian. Interaction between mono-pile and porous seabed under cnoidal wave and pile rocking[J]. Journal of Shanghai Jiao Tong University, 2019, 53(1):85-92. |
| [15] | JENG D S, RAHMAN M S, LEE T L. Effects of inertia forces on wave-induced seabed response[J]. International Journal of Offshore and Polar Engineering, 1999, 9(4):7. |
| [16] | ARANY L, BHATTACHARYA S, MACDONALD J, et al. Simplified critical mudline bending moment spectra of offshore wind turbine support structures[J]. Wind Energy, 2015, 18(12):2171-2197. |
| [17] | ABHINAV K A, SAHA N. Coupled hydrodynamic and geotechnical analysis of jacket offshore wind turbine[J]. Soil Dynamics and Earthquake Engineering, 2015, 73:66-79. |
| [18] | ZHANG Q, ZHOU X L, WANG J H, et al. Wave-induced seabed response around an offshore pile foundation platform[J]. Ocean Engineering, 2017, 130:567-582. |
| [19] | HSU J R C, JENG D S. Wave-induced soil response in an unsaturated anisotropic seabed of finite thickness[J]. International Journal for Numerical and Analytical Methods in Geomechanics, 1994, 18(11):785-807. |
| [20] | 单铁兵, 杨建民, 李欣, 等. 水流对立柱周围波浪爬升特性的影响[J]. 上海交通大学学报, 2014, 48(1):116-124. |
| [20] | SHAN Tiebing, YANG Jianmin, LI Xin, et al. Current effects on wave run-up characteristics around column[J]. Journal of Shanghai Jiao Tong University, 2014, 48(1):116-124. |
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