岩土力学
巖土力學
암토역학
ROCK AND SOIL MECHANICS
2013年
10期
3003-3010
,共8页
大变形固结%沉降%黏性泥砂%数值模型%沉降柱试验
大變形固結%沉降%黏性泥砂%數值模型%沉降柱試驗
대변형고결%침강%점성니사%수치모형%침강주시험
large strain consolidation%settlement%deposited sediment%numerical model%settlement column experiment
沉积形成的水底黏性泥砂自重固结过程表现出显著非线性大变形固结特征,应采用大变形固结理论进行泥砂沉积固结计算。基于软黏土一维非线性大应变固结理论,应用有效应力、渗透系数与孔隙比间扩展幂次函数固结本构关系,由达西定律、有效应力原理、连续介质方程等建立大变形固结控制方程,根据固结单元孔隙水渗流、单元变形与泥砂沉积层固结沉降耦合关系形成黏性泥砂大变形自重固结数值模型。泥砂自重作为固结荷载,数值模型假定沉积泥砂各向同性且固结沉降应变、孔隙水渗流仅发生于竖直方向,为一维单向沉积固结过程;采用泥砂沉降柱试验确定泥砂非线性扩展幂次函数关系参数。模型应用中,划分竖向固结单元,由沉积泥砂固结本构关系确定各固结单元有效应力及超孔隙水应力,通过超孔隙水应力时间维度上的消散过程及各固结参数间的耦合关系计算泥砂固结沉降。数值模型计算结果表明,沉积黏性泥砂自重固结初期表现为有效应力调整过程,初始有效应力与孔隙比根据固结本构关系匹配调整为扩展幂次函数关系;沉积泥砂应变与应力固结度存在20%左右误差,泥砂固结沉降发展快于超孔隙水应力消散过程,证明沉积泥砂固结沉降变形的发展与超孔隙水应力消散并非同步耦合。计算模型应用于室内沉降柱试验模拟淤积黏性泥砂自重固结沉降预测中,模型输出与试验结果符合良好。
沉積形成的水底黏性泥砂自重固結過程錶現齣顯著非線性大變形固結特徵,應採用大變形固結理論進行泥砂沉積固結計算。基于軟黏土一維非線性大應變固結理論,應用有效應力、滲透繫數與孔隙比間擴展冪次函數固結本構關繫,由達西定律、有效應力原理、連續介質方程等建立大變形固結控製方程,根據固結單元孔隙水滲流、單元變形與泥砂沉積層固結沉降耦閤關繫形成黏性泥砂大變形自重固結數值模型。泥砂自重作為固結荷載,數值模型假定沉積泥砂各嚮同性且固結沉降應變、孔隙水滲流僅髮生于豎直方嚮,為一維單嚮沉積固結過程;採用泥砂沉降柱試驗確定泥砂非線性擴展冪次函數關繫參數。模型應用中,劃分豎嚮固結單元,由沉積泥砂固結本構關繫確定各固結單元有效應力及超孔隙水應力,通過超孔隙水應力時間維度上的消散過程及各固結參數間的耦閤關繫計算泥砂固結沉降。數值模型計算結果錶明,沉積黏性泥砂自重固結初期錶現為有效應力調整過程,初始有效應力與孔隙比根據固結本構關繫匹配調整為擴展冪次函數關繫;沉積泥砂應變與應力固結度存在20%左右誤差,泥砂固結沉降髮展快于超孔隙水應力消散過程,證明沉積泥砂固結沉降變形的髮展與超孔隙水應力消散併非同步耦閤。計算模型應用于室內沉降柱試驗模擬淤積黏性泥砂自重固結沉降預測中,模型輸齣與試驗結果符閤良好。
침적형성적수저점성니사자중고결과정표현출현저비선성대변형고결특정,응채용대변형고결이론진행니사침적고결계산。기우연점토일유비선성대응변고결이론,응용유효응력、삼투계수여공극비간확전멱차함수고결본구관계,유체서정률、유효응력원리、련속개질방정등건립대변형고결공제방정,근거고결단원공극수삼류、단원변형여니사침적층고결침강우합관계형성점성니사대변형자중고결수치모형。니사자중작위고결하재,수치모형가정침적니사각향동성차고결침강응변、공극수삼류부발생우수직방향,위일유단향침적고결과정;채용니사침강주시험학정니사비선성확전멱차함수관계삼수。모형응용중,화분수향고결단원,유침적니사고결본구관계학정각고결단원유효응력급초공극수응력,통과초공극수응력시간유도상적소산과정급각고결삼수간적우합관계계산니사고결침강。수치모형계산결과표명,침적점성니사자중고결초기표현위유효응력조정과정,초시유효응력여공극비근거고결본구관계필배조정위확전멱차함수관계;침적니사응변여응력고결도존재20%좌우오차,니사고결침강발전쾌우초공극수응력소산과정,증명침적니사고결침강변형적발전여초공극수응력소산병비동보우합。계산모형응용우실내침강주시험모의어적점성니사자중고결침강예측중,모형수출여시험결과부합량호。
Large strain consolidation theory is applied to calculate deposited cohesive sediment weight deposition and consolidation for the significant nonlinear large strain characteristics. Based on soft soil one-dimensional general large strain consolidation theory and the application of quasi-power functional consolidation constitutive relationships between effective stress, permeability and void ratio, nonlinear large strain consolidation governing equation can be built up according to Darcy law, effective stress principle as well as the soil continuous equation. By the coupling relationship of pore water seepage, element deformation and weight consolidation settlement, a full cohesive sediment weight consolidation numerical model is developed for the nonlinear large strain characteristics. With the fact that deposited sediment weight is as the consolidation loading, the new developed model assumes the deposited sediment layer is homogenous, and the consolidation settlement along with the pore water seepage only occurs in vertical direction, and then the sediment consolidation process can be seen as one dimensional weight consolidation. Moreover, nonlinear quasi-power consolidation constitutive relationship parameters are determined by the cohesive sediment settlement column experiment. Consolidation elements are applied to evaluate the effective stress, excessive pore pressure of different depths, and deposited sediment consolidation settlement is determined by the dissipation of excessive pore pressure in time scale. Numerical model performance shows that there is a clear adjustment process for the relationship of deposited layer effective stress and the void ratio according to the quasi-power functional constitutive relationship in the initial stage. An approximate 20% error between stress and strain consolidation degree means that deposited sediment consolidation settlement develops faster than excessive pore pressure dissipation, which also proves the asynchronous coupling relationship of consolidation deformation and excessive pore pressure dissipation in large strain consolidation. According to the numerical model performances in cohesive sediment consolidation with settlement column experiment, the new developed model outputs show a well agreement with the measured one.