平面应变条件下不同裂隙方向原状膨胀土变形破坏性状与剪切带演化特征

富含裂隙是膨胀土的重要特性之一,原生裂隙以及受力过程中的裂隙扩展对土的力学行为影响显著。为了调查裂隙对膨胀土的变形规律与破坏模式的影响,借助改进型真三轴仪,对不同原生裂隙主方向角的原状膨胀土(I型裂隙试样长轴垂直优势裂隙方向、II型裂隙试样长轴45°斜交优势裂隙方向、III型裂隙试样长轴平行优势裂隙方向),开展固结排水平面应变剪切试验,并利用数字图像相关(digital image correlation,简称DIC)技术分析变形规律,重点研究裂隙影响的变形局部化特征。结果表明:同一围压作用时,II型裂隙试样的峰值应力最小,应力-应变曲线呈应变软化型,其破坏类型为滑动破坏;I型裂隙试样峰值应力最大,且I型裂隙试样与III型裂隙试样的应力-应变曲线呈应变硬化型。I型裂隙试样的破坏类型为压缩剪切破坏,III型裂隙试样的破坏类型随围压不同而存在差异。同一围压作用下,I型裂隙试样产生的剪切带倾角较其他裂隙类型样品小,且基本不随围压变化。II型裂隙试样的剪切带沿原生裂隙面发育形成,其倾角大小随围压变化并无明显规律,围压影响II型裂隙土试样剪切带发育的数量。对于III型裂隙试样,围压影响剪切带发育类型,且随着围压增大,主剪切带倾角减小。利用Roscoe理论得到不同裂隙方向土样的剪切带倾角大小与试样实际破坏时剪切带的倾角较为符合。该试验为研究裂隙性膨胀土力学特征各向异性奠定了基础。

湛江结构性黏土在三维应力下的力学特性与强度准则

为了探究湛江结构性黏土在三维应力状态下的力学特性以及结构性对其强度准则的影响,开展了一系列不排水条件下不同中主应力比b值等平均主应力p真三轴试验和平面应变试验。结果表明:p小于与大于结构屈服应力,整体上广义剪应力q-大主应变ε_(1)曲线分别呈现为应变软化型与轻度应变硬化型;不同b值下的q-ε_(1)曲线形态相近,但随b值增加,峰值点q对应的大主应变呈现减小的规律;且有效黏聚力随着b值增大而减小,有效摩擦角随b值增大而增大,平面应变试验有效黏聚力和摩擦角的值则介于b=0.25和b=0.50对应的有效黏聚力和摩擦角之间;受结构性的影响,湛江黏土在π面上的强度准则在p值小于结构屈服应力时接近于Lade-Duncan准则,而在p值大于结构屈服应力时更加接近基于Mises准则和Lade-Duncan准则的广义非线性强度理论;平面应变试验结果表明,湛江黏土在平面应变加卸载条件下破坏时的b值在0.18~0.29之间,破坏时的强度可以用基于广义Mises与Lade-Duncan平面应变强度准则的广义平面应变强度准则近似估计。

湛江结构性黏土自钻旁压试验的加载速率效应

作为一种具有高结构屈服强度的灵敏性黏土,湛江黏土力学性质的加载速率效应值得关注。为了研究湛江黏土原位力学性质的加载速率效应,开展了不同加载速率的自钻旁压试验,分析应力速率对湛江黏土原位不排水抗剪强度、线性刚度以及剪切模量非线性衰减特性的影响。结果表明:应力速率越大,不排水抗剪强度就越大,二者之间具有良好的线性关系,这一变化关系不同于文献中控制应变速率的研究结果;线性割线剪切模量G_(ur)随应力速率的增大而增大,经相应速率下G_(ur)归一化后的不排水抗剪强度落于较窄的数值区间内,表明应力速率对峰值强度对应的应变影响很小;加载速率越大,切线剪切模量G_(t)衰减幅度越大、衰减越迅速、G_(t)-γ衰减曲线越陡,但对于各应力速率,G_(t)均约在g=0.1%时衰减至小于G_(ur);加载速率影响了各应变区间内G_(t)的衰减幅度和速度,加载速率越小,衰减集中发生于越低的应变水平。研究指出湛江黏土特殊的微观结构是控制其力学性质加载速率效应的主导因素,并通过开展原状土样和重塑土样的室内超微型贯入试验予以初步印证。认为应当重视土体原位力学性质的加载速率效应,同时关注加载速率历史对土体蠕变性质的影响。

Evolution of macro-meso properties of intact loess under long-term seepage and its influence on irrigation-induced loess flowslides

The loess tableland provides an excellent site for people to live and cultivate.However,flowslides occur frequently on the slope of loess tablelands due to agriculture irrigation,resulting in serious economic losses and casualties.The structure degradation effect of irrigation water seepage on intact loess leads to a weakening of its mechanical properties,which may be responsible for the recurrent occurrence of flowslides in irrigated loess tablelands.In this paper,seepage tests and triaxial tests were carried out to investigate the evolution of the microstructure and undrained shear properties of intact loess during seepage.The results show that water seepage leads to a significant decrease in pore water ion concentration and migration of fine particles with water flow,but no noticeably change in mineral composition.During seepage,the metastable structure of intact loess collapses,the fine particles disperse around the skeleton particle to fill the pores,and the total porosity decreases.The permeability coefficient gradually decreases with seepage time and then tends to a constant.The saturated intact loess shows strongly contractive behavior during undrained shear and has considerable liquefaction potential.After seepage,the intact loess is characterized by more rapid build-up of pore water pressure and more intense strain-softening during shearing and has lower shear strength(including peak strength and steady-state strength).In irrigated loess tablelands,long-term seepage could weaken the shear strength of intact loess and increases its liquefaction potential,which contributes to the initiation of loess flowslide failure and the movement with high-speeds and long run-outs.