Analytical solution for penetration response of steel catenary riser at touchdown zone on bilinear seabed
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摘要: 钢悬链线立管触地段管土作用对管线埋深及管线寿命的影响显著。对触地段管土相互作用p-y曲线用二段线弹性近似,考虑了土体刚度的非线性,更好地反映土体刚度随管线贯入深度增大而降低的特性。根据贯入深度建立了多段管线控制微分方程,结合边界条件求得静力状态下管线贯入响应的解析表达式。在验证解析解正确的基础上,对土体刚度变化、泥线处土体不排水抗剪强度、土体强度梯度、外部弯矩荷载及管线自重下的管线贯入响应进行了分析。结果表明二段线弹性模型中得到的土体阻力与p-y曲线更接近。管线贯入深度随泥线处土体不排水抗剪强度、土体强度梯度的增大而减小。外部弯矩荷载的增大会使管线贯入深度及触地段管线的最大剪力变大。管线自重增加会使管线贯入深度增加,弯矩增大。Abstract: The pipe-soil interaction at touchdown zone (TDZ) of steel catenary riser (SCR) has important influences on the penetration depth and fatigue life of pipelines. A model considering non-linearity of soil stiffness is established by using bilinear linear soil stiffness approximation of p-y curve. The model reflects the characteristics of the soil stiffness deceasing with the increase of the penetration depth of the pipelines. The differential equation for pipelines is established and the analytic expression for the penetration response of pipelines in static state is obtained based on boundary conditions. After justifying the correctness of the model, four factors that influence the penetration response of pipelines are analyzed: the shear strength of mudline, the gradient of soil shear strength, the external bending moment load and the weight of pipelines. The results show that the penetration depth of pipelines increases with the decrease of the shear strength of mudline and the gradient of the soil shear strength. And if the external bending moment load increases, the penetration depth of pipelines will increase and the maximum shear force will also increase. Due to the increase of weight of pipelines, the penetration depth of pipelines and bending moment will increase.
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Keywords:
- steel catenary riser /
- pipe-soil interaction /
- soil stiffness /
- analytical solution
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[1] WHITE D J, RANDOLPH M F.Seabed characterisation and models for pipeline-soil interaction[J]. International Journal of Offshore and Polar Engineering, 2007, 17(3): 193-204. [2] THETI R.Soil interaction effects on simple-catenary riser response[J]. Pipes & Pipelines International, 2001, 46(3): 15-24. [3] WILLIS N R T, WEST P T J. Interaction between deepwater catenary risers and a soft seabed: large scale sea trials[C]// Offshore Technology Conference. Houston, 2001. [4] ELOSTA H, INCECIK A, HUANG S.Seabed interaction modeling effects on the global response of catenary pipeline: a case study[J]. American Society of Mechanical Engineers, 2014, 136(3): 52-68. [5] BRIDGE C, LAVER K, CLUKEY E, EVANS T.Steel catenary riser touchdown point vertical interaction models[C]// Offshore Technology Conference. Houston, 2004. [6] AUBENY C P, BISCONTIN G.Seafloor-riser interaction model[J]. International Journal of Geomechanics, 2009, 9: 133-141 [7] LENCI S, CALLEGARI M.Simple analytical models for the J-lay problem[J]. Acta Mechanica, 2005, 178(1): 23-39. [8] REZAZADEH K, 陆钰天, 白勇, 等. 钢悬链线立管与海底相互作用和疲劳分析[J]. 哈尔滨工程大学学报, 2014, 35(2): 155-160.
(REZAZADEH K, LU Yu-tian, BAI Yong, et al.The interaction between the steel catenary riser and the seabed and the analysis of fatigue[J]. Journal of Harbin Engineering University, 2014, 35(2): 155-160. (in Chinese))[9] YUAN F, RANDOLPH M F, WANG L Z, et al.Refined analytical models for pipe-lay on elasto-plastic seabed[J]. Applied Ocean Research, 2014, 48(4): 292-300. [10] HETENYI M.Beams on elastic foundation[M]. Ann Arbor: University of Michigan Press, 1946. [11] SHIRI H.Influence of seabed trench formation on fatigue performance of steel catenary risers in touchdown zone[J]. Marine Structures, 2014, 36: 1-20. [12] AUBENY C P, SHI H, MURFF J D.Collapse loads for a cylinder embedded in trench in cohesive soil[J]. International Journal of Geomechanics, 2005, 5(4): 320-325. [13] RANDOLPH M F, WHITE D.Pipeline embedment in deep water: processes and quantitative assessment[C]// Offshore Technology Conference. Houston, 2008. [14] BRIDGE C.Effects of seabed interaction on steel catenary risers[D]. Surrey: University of Surrey, 2005. -
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