半透水边界下分数阶黏弹性饱和土一维固结特性分析

为描述饱和土体的流变特性,引入分数阶导数Kelvin-Voigt黏弹性模型,采用解析方法对半透水边界下的分数阶黏弹性饱和土一维固结特性进行了研究。分别对骤加恒载下饱和土一维固结微分方程和分数阶Kelvin-Voigt黏弹性本构方程进行Laplace变换,并联立求解得到了双边半透水边界条件下分数阶黏弹性饱和土在Laplace变换域内的解析表达式。通过Crump方法实现Laplace数值反演,得到时间域内的半解析解。将所得到的解分别退化为分数阶黏弹性饱和土一维固结半解析解和双边半透水黏弹性饱和土一维固结半解析解,结果与已有文献半解析解相同,验证了提出的双边半透水边界条件下分数阶黏弹性饱和土一维固结解的可靠性。通过算例考察了半透水边界条件和分数阶黏弹性饱和土参数对一维固结特性的影响。研究表明,双边半透水边界下分数阶黏弹性饱和土一维固结发展过程与半透水边界条件、分数阶次和黏滞系数有关,且土体的压缩模量对饱和土一维固结最终沉降量有显著影响。     

分数阶导数黏弹性饱和土体一维固结半解析解

将分数阶微积分理论引入Kelvin-Voigt本构模型,以描述黏弹性饱和土体的力学行为。对饱和土体一维固结方程和上述分数阶导数Kelvin-Voigt本构方程实施Laplace变换,联立求解得到变换域内有效应力和沉降的解析解。采用Crump方法实现Laplace数值反演,从而获得了物理空间一维固结问题的半解析解,并将其退化到弹性和黏弹性两种经典情形,分析表明,它与经典解析解完全相同,这证明了经典弹性和黏弹性解析解可视为本研究提出分数阶导数黏弹性解的特例。开展了参数研究,即分析了相关各种参数对固结沉降的影响。研究表明,瞬时荷载情形下分数阶导数黏弹性饱和土体一维固结最终沉降量与黏滞系数和分数阶次无关,而不同黏滞系数和分数阶次对固结时间有较大影响。其研究结果有助于深入认识黏弹性饱和土体的固结力学行为。     

变荷载下连续排水边界黏弹性地基一维固结性状分析

在考虑软黏土流变特性的基础上,结合工程实际,引入连续排水边界条件,建立了变荷载下连续排水边界黏弹性地基一维固结模型。通过分离变量法与常数变易法,求得了变荷载作用及连续排水边界条件下的饱和软黏土一维固结模型的解析解,进一步研究了透水边界条件和土体参数对超孔隙水压力、有效应力的影响。研究结果表明:上下边界透水性的不同会直接影响超孔隙水压力的变化;越靠近透水性大的边界处的土体固结速度越快,且随着其离排水边界的距离减小,对固结速度的影响逐渐增大;另外,软土层的渗透系数、Kelvin体弹簧的弹性模量和黏滞系数等对土颗粒间的有效应力影响较大。     

任意荷载下双面半透水边界分数阶导数黏弹性饱和土层一维固结

基于Terzaghi一维固结理论,分析了考虑半透水边界条件的分数阶导数黏弹性饱和土层在随时间变化的任意荷载作用下一维固结问题。首先,应用Laplace变换联立求解饱和土层一维固结微分方程和分数阶Kelvin-Voigt黏弹性本构方程,推导出有效应力和沉降在Laplace变换域内的解析解,采用Crump方法进行Laplace逆变换,得到了时间域内的半解析解。然后将本文得到的半解析解分别退化为半透水边界条件下基于黏弹性假设的一维固结半解析解和双面透水边界条件下基于分数阶黏弹性假设的一维固结半解析解,结果与已有文献的半解析解相同,验证了本研究所提出解的可靠性。最后通过算例分别考察了半透水边界参数、分数阶黏弹性模型参数和荷载参数对饱和土层固结沉降的影响。研究表明,半透水边界条件参数、分数阶次与黏滞系数主要影响饱和土层固结的发展快慢,而饱和土层的最终沉降量主要受到土层压缩模量的影响;另外,饱和土层的固结规律与外荷载变化规律一致。     

一种分析软土黏弹性的分数导数开尔文模型

软土是一种黏、弹、塑性材料,采用分数微积分模型来研究软土的蠕变规律目前尚未见到。选取了珠江三角洲南沙地区典型软土作为研究对象,在对其进行大量相关试验的基础上,采用含分数阶导数的开尔文模型来模拟该地区软土的蠕变规律,讨论了含分数阶导数的开尔文模型的蠕变柔量和松驰模量及其应用。与传统的开尔文模型相比较,分数阶导数的开尔文模型可以更好地拟合蠕变曲线,而且其形式简单、统一,在计算过程中需要调整的参数很少。可以预见,含分数阶导数的开尔文体在软土的流变本构研究领域及其计算中将有着广泛的应用前景。     

连续排水边界下考虑变荷载的软土一维非线性固结分析

土体往往具有非线性压缩特性,不同压缩特性下土体的固结规律存在差异。综合考虑土体非线性特性、变荷载作用以及连续排水边界条件建立了一维固结方程。采用无条件稳定的有限差分法和半解析法对固结方程进行了求解,两种解答方法的可靠性通过连续排水边界条件退化以及两种解答结果对比得到验证。在有限差分法解答的基础上,详细分析了界面参数、荷载参数以及非线性参数对土体固结的影响。结果表明：连续排水边界的界面参数取值越大,则超静孔隙水消散速率及土体沉降速率越大,但界面参数取值对最终沉降量没有影响;超静孔隙水压力在加载阶段逐渐增大,在恒载阶段逐渐消散;加载速率越大,则超静孔隙水压力峰值越大,并且土体固结速率越快,说明延长施工周期有利于降低超静孔隙水压力的影响;工程中要准确预测土体固结速率绝非易事,采用固结理论预测时需保证土体模型、边界条件以及土体计算参数等因素的准确性。     

基于分数阶Kelvin模型的饱和黏土一维流变固结分析

引入基于Caputo分数导数的弹壶元件修正Kelvin模型,以描述饱和黏土的一维流变本构关系。沿用Terzaghi饱和土一维固结理论的假设推导流变固结方程,引入Laplace变换和基于Fourier级数展开的Laplace数值逆变换解法进行数值求解。通过与基于整数阶导数模型解析解的对比,证明数值解法的有效性。通过对文献中一维流变固结试验结果的模拟,验证修正Kelvin模型的适用性。然后分析弹壶元件中分数导数阶数和黏滞系数对地基流变固结进程的影响。计算结果表明,在固结开始相当长的一段时间内,孔隙水压的整体消散速度要快于Terzaghi一维固结理论,但在固结后期则会慢于后者;而且在整个固结过程中,地基沉降速率都要慢于后者。总体来看,地基沉降滞后于孔压消散,并且分数导数阶数越小或黏滞系数越大,这种现象就越明显,而且沉降稳定需要的时间越长。     

循环荷载下黏弹性饱和土层的一维固结

针对单层黏弹性地基Merchant模型,运用Laplace变换,求得频域内单层黏弹性地基的一维固结解。通过Laplace逆变换,计算了单层黏弹性地基在任意循环荷载下的有效应力及平均固结度。此外,结合工程实例,研究了Merchant模型各参数对循环荷载下黏弹性地基固结的影响。结果表明,在黏弹性地基的固结过程中,有效应力和沉降的发展速率是不一致的,黏壶的存在使地基固结初期的有效应力增长加快,而使固结后期的有效应力增长减慢,同时使变形的发展滞后于有效应力的发展。研究结果亦表明,循环荷载下土体的固结对独立弹簧模量的变化要比Kelvin体中弹簧模量的变化敏感。     

基于等效黏弹性的变阶分数阶岩石损伤蠕变模型

基于分数阶Zener模型与时变黏性Zener模型之间的等效黏弹性,突出弛豫时间在岩石流变黏弹性演变过程中的重要性。当弛豫时间趋近于无穷大,蠕变过程中的黏性演变等同于松弛过程中的黏性演变,并且建立了与弛豫时间相关的损伤因子,解释了损伤因子在岩石流变变形过程的物理意义。利用弛豫时间建立分数阶变阶函数,依此构造变阶分数阶损伤蠕变模型,并且将模型推广到三向应力状态,给出三向应力状态下变阶分数阶损伤蠕变模型。最后基于砂岩的三轴蠕变试验数据,验证了三轴状态下变阶分数阶损伤蠕变模型的可应用性和合理性,试验数据与模型拟合曲线吻合度较高,可以较好地描述蠕变全过程力学行为。模型拟合参数的有效性得到分析和验证,增加了模型在其他复杂应力环境下的可应用性。     

基于非牛顿指数渗流和分数阶Merchant模型的一维流变固结分析

为进一步深入分析饱和黏性土的一维流变固结机制,引入Koeller定义的弹壶元件修正Merchant模型,并以此描述土骨架的黏弹性变形行为;同时引入非牛顿指数渗流模型描述流变固结中的非达西渗流,推导出一个新的饱和黏性土一维流变固结方程,并用隐式有限差分法进行数值求解。通过与有关文献中退化模型结果的对比,验证了有限差分算法的有效性。在此基础上,分析非达西渗流模型参数以及分数阶Merchant流变模型参数对流变固结过程的影响。计算结果表明:分数导数阶数和黏滞系数对地基沉降的影响比对孔压消散的影响更为明显,且分数导数阶数越小或黏滞系数越大,地基沉降需要的时间越长。同时,比起达西渗流,非牛顿指数渗流会延缓地基中的孔压消散,使得沉降发展变慢。另外,考虑流变效应时地基沉降要慢于孔压的消散。     

Semi-analytical solution for one-dimensional consolidation of fractional derivative viscoelastic saturated soils

This paper presents a semi-analytical solution to one-dimensional consolidation equation of fractional derivative Kelvin-Voigt viscoelastic saturated soils subjected to different time-dependent loadings. The theory of fractional calculus is first introduced to Kelvin-Voigt constitutive model to describe consolidation behavior of viscoelastic saturated soils. By applying Laplace transform upon the one-dimensional consolidation equation of saturated soils, the analytical solutions of effective stress and settlement in the Laplace transform domain are obtained. The present solutions are more general and have good agreements with available solutions from the literature, and are degenerated into ones for one-dimensional consolidation of elastic and viscoelastic saturated soils.     

One-dimensional consolidation of soil under multistage load based on continuous drainage boundary

In engineering practice, a rapid loading rate can result in ground failure when the strength of soft soils is relatively low, and a multistage loading scheme is always utilized to deal with this situation. Firstly, under a multistage load and the continuous drainage boundary, an analytical solution of excess pore-water pressure and consolidation degree is obtained by virtue of the superposition formula of excess pore-water pressure, and a more general continuous drainage boundary under arbitrary time-dependent load is developed. Then, a comparison with existing analytical solutions is conducted to verify the present solution. A preliminary attempt on applying the continuous drainage boundary into the finite element model is made, and the feasibility of the numerical model for the one-dimensional consolidation under the continuous drainage boundary is verified by comparing the results calculated by FEM with that from present analytical solution. Finally, the consolidation behavior of soil is investigated in detail for different int erface parameters or loading scheme. The results show that, in land reclamation projects, a horizontal drain should be placed close to the boundary with a smaller interface parameter to improve the consolidation efficiency. The degree of consolidation is also related to the applied time-dependent load and interface parameters.     

One-dimensional self-weight consolidation with continuous drainage boundary conditions: Solution and application to clay-drain reclamation

Traditional consolidation theories cannot provide good predictions of consolidation settlement in land reclamation because of their assumptions that the influence of soil's self-weight is often neglected, and the drainage boundary is considered as fully pervious/impervious. In view of these limitations, an analytical solution is derived for one-dimensional self-weight consolidation problems with a continuous drainage boundary using the finite Fourier sine transform method. Following the classical Terzaghi's small strain theory, the soil's self-weight is considered to produce consolidation settlement in dredged materials with a constant coefficient of consolidation. The continuous drainage boundary can essentially describe the time-dependent variation of drainage capacity at the interface between two adjacent soil layers. By reducing the interface parameters, the effectiveness of the calculation is demonstrated against the Terzaghi's solution. The influence of interface parameters and soil's self-weight stress coefficient on self-weight consolidation is discussed. As expected, the rate of consolidation considering the self-weight stress is faster, although the dependency of consolidation rate on the material property of void ratio is neglected. Moreover, the plane of maximum excess pore-water pressure is estimated as a function of time factor, based on which a design chart is developed to optimize the layout of horizontal drains in land reclamation.     

具有球形空腔饱和土分数导数 黏弹性土的动力特性

将土骨架视为具有分数阶导数本构关系的黏弹性体,基于Biot两相饱和介质模型,建立具有球形空腔饱和分数导数黏弹性土体稳态振动的控制方程。通过引入势函数,得到球对称情形下具有球形空腔饱和分数导数黏弹性土体的位移、应力和孔隙流体压力等解析表达式。考察分数导数模型参数和饱和土参数等对土体振动特性的影响,结果表明,流体压缩性对饱和土体的动力特性有显著影响,而土骨架压缩性和流-固耦合系数的影响相对较小;分数导数阶数对土体动力特性的影响与材料参数比的取值有关。同时,边界不排水条件下饱和土体的动力响应大于排水条件下饱和土体的动力响应。     

Semi-analytical solutions to one-dimensional consolidation for unsaturated soils with symmetric semi-permeable drainage boundary

This paper presents semi-analytical solutions to Fredlund and Hasan’s one-dimensional consolidation for unsaturated soils under symmetric semi-permeable drainage boundary conditions. Two variables are introduced to transform two coupled governing equations of pore-air and pore-water pressures into an equivalent set of partial differential equations, which are easily solved by the Laplace transform. Then, the pore-air and pore-water pressures, and soil settlement are obtained in the Laplace domain. Crump’s method is adopted to perform the inverse Laplace transform in order to obtain semi-analytical solutions in time domain. It is shown that the present solution is more applicable to various types of drainage boundary conditions, and in a good agreement with existing solutions from the literature. Furthermore, several numerical examples are provided to investigate the consolidation behavior of an unsaturated single-layer soil with traditional drainage boundary (single or double), and single-sided and double-sided semi-permeable drainage boundaries. Finally, it illustrates the changes in pore-air and pore-water pressures and soil settlement with time at different values of symmetric semi-permeable drainage boundary conditions parameters. In addition, parametric studies are conducted by the variations of pore-air and pore-water pressures at different ratios of air-water permeability coefficient and the depth.     

非等温分布条件下考虑半透水边界时饱和黏土的一维固结解析解

温度的变化会导致土体的物理力学性质改变,且在一些实际工程中,饱和黏土会处于非等温分布状态。为此,针对非等温分布条件下饱和黏土的一维固结问题,考虑了更具普遍性的半透水边界,通过某些假定推导了单级线性加荷形式下饱和黏土一维固结控制方程,并利用分离变量法求解得到了控制方程的解析解。通过将所提解析解分别与已有解析解和有限差分解展开对比分析,验证了所提解答的正确性。基于所提解析解,利用某一算例分析了温度梯度、半透水边界参数及加荷时间对固结性状的影响。结果表明：温度梯度 M 越大,土体的渗透性越大,土体的固结速率越快;半透水边界参数 R1和 R2越大,相同时间内土体的超孔隙水压力越小,土体的平均固结度越大;土体的平均固结度随加荷时间 tc 的增大而减小,这主要是由于加荷阶段所施加的外荷载小于最终荷载,但加荷时间tc的延长可一定程度减小土体中产生的最大超孔隙水压力。