Variation of hydraulic gradient in nonlinear finite strain consolidation 被引量：1

Variation of hydraulic gradient in nonlinear finite strain consolidation

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摘要 In the research field of ground water, hydraulic gradient is studied for decades. In the consolidation field, hydraulic gradient is yet to be investigated as an important hydraulic variable. So, the variation of hydraulic gradient in nonlinear finite strain consolidation was focused on in this work. Based on lab tests, the nonlinear compressibility and nonlinear permeability of Ningbo soft clay were obtained. Then, a strongly nonlinear governing equation was derived and it was solved with the finite element method.Afterwards, the numerical analysis was performed and it was verified with the existing experiment for Hong Kong marine clay. It can be found that the variation of hydraulic gradient is closely related to the magnitude of external load and the depth in soils. It is interesting that the absolute value of hydraulic gradient(AVHG) increases rapidly first and then decreases gradually after reaching the maximum at different depths of soils. Furthermore, the changing curves of AVHG can be roughly divided into five phases. This five-phase model can be employed to study the migration of pore water during consolidation. In the research field of ground water, hydraulic gradient is studied for decades. In the consolidation field, hydraulic gradient is yet to be investigated as an important hydraulic variable. So, the variation of hydraulic gradient in nonlinear finite strain consolidation was focused on in this work. Based on lab tests, the nonlinear compressibility and nonlinear permeability of Ningbo soft clay were obtained. Then, a strongly nonlinear governing equation was derived and it was solved with the finite element method.Afterwards, the numerical analysis was performed and it was verified with the existing experiment for Hong Kong marine clay. It can be found that the variation of hydraulic gradient is closely related to the magnitude of external load and the depth in soils. It is interesting that the absolute value of hydraulic gradient（AVHG） increases rapidly first and then decreases gradually after reaching the maximum at different depths of soils. Furthermore, the changing curves of AVHG can be roughly divided into five phases. This five-phase model can be employed to study the migration of pore water during consolidation.

作者谢新宇黄杰卿王文军李金柱

机构地区 Research Center of Coastal and Urban Geotechnical Engineering School of Civil Engineering & Architecture Key Laboratory of Soft Soils and Geoenvironmental Engineering of Ministry of Education (Zhejiang University)

出处《Journal of Central South University》 SCIE EI CAS 2014年第12期4698-4706,共9页 中南大学学报（英文版）

基金 Project(51378469)supported by the National Natural Science Foundation of China Project(Y1111240)supported by the Zhejiang Provincial Natural Science Foundation of China Project(2013A610196)supported by the Natural Science Foundation of Ningbo City,China

关键词 hydraulic gradient nonlinearity finite strain consolidation 非线性控制方程水力梯度固结过程有限应变有限元法数值分析海洋粘土变化曲线

分类号 TV13 [水利工程—水力学及河流动力学]

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