Cyclic behavior of reinforced sand under principal stress rotation

Although the cyclic rotation of the principal stress direction is important,its effect on the deformation behavior and dynamic properties of the reinforced soil has not been reported to date.Tests carried out on large-scale hollow cylinder samples reveal that the cyclic rotation of the principal stress direction results in significant variations of strain components(ε,ε,εand γ) with periodic characteristics despite the deviatoric stress being constant during tests.This oscillation can be related to the corresponding variations in the stress components and the anisotropic fabric that rotate continuously along the principal stress direction.Sand under rotation appears to develop a plastic strain.Similar trends are observed for reinforced sand,but the shear interaction,the interlocking between particles and reinforcement layer,and the confinement result in significant reductions in the induced strains and associated irrecoverable plastic strains.Most of the strains occur in the first cycle,and as the number of cycles increases,the presence of strains becomes very small,which is almost insignificant.This indicates that the soil has reached anisotropic critical state(ACS),where a stable structure is formed after continuous orientation,realignment and rearrangement of the particles accompanied with increasing cyclic rotation.Rotation in the range of 60°-135° produces more induced strains even in the presence of the reinforcement,when compared with other ranges.This relates to the extension mode of the test in this range in which σ>σand to the relative approach between the mobilized plane and the weakest horizontal plane.Reinforcement results in an increase in shear modulus while it appears to have no effect on the damping ratio.Continuous cycles of rotation result in an increase in shear modulus and lower damping ratio due to the densification that causes a decrease in shear strain and less dissipation of energy.

列车荷载作用下压实花岗岩残积土累积变形特性试验研究

为研究列车荷载作用下应力及湿化条件对压实花岗岩残积土累积变形特性的影响,以围压、动应力幅值、含水率为变量,对压实花岗岩残积土进行循环空心扭剪和循环定向加载试验。结果表明:循环扭剪应力路径下主应力轴旋转效应增加了试样的累积变形量,甚至改变了累积变形的发展模式,该影响程度随试样含水率的增大而增大;试样的累积应变发展速率在加载初期(N<100)时完成大幅度衰减,围压增大可加快累积应变发展速率的衰减,动应力幅值的增加会延长累积应变发展速率的衰减时间,循环扭剪加载时试样的累积应变发展速率衰减程度小于循环定向加载试验,含水率越高该效应越显著。通过预测模型能够对两种动力加载应力路径下的稳定型和发展型累积应变发展曲线能够进行拟合,对压实花岗岩残积土的累积变形作出较好预测。

初始剪应力作用下饱和粉土液化流动特性试验研究

饱和粉土在地震作用下会发生液化变形,从而导致建立在其上的建(构)筑物发生破坏。工程场地区域内粉土单元通常存在初始剪应力作用,为探究初始剪应力对饱和粉土液化特性的影响,将液化后粉土视为流体进行了一系列循环扭剪试验研究。试验结果表明,初始剪应力对饱和粉土剪应力-剪应变率曲线影响显著,随着初始剪应力τ_(s)的增大,剪应力-剪应变率曲线由“椭圆形”向“哑铃形”过渡逐渐转变为由“镰刀形”向“椭圆形”至“锤形”过渡;表观黏度η与振次N的衰减曲线随着τ_(s)的增大先降低再抬升,平均流动系数κ与振次N的增长曲线发展速度随着τ_(s)的增大先加快后减慢,固液相变孔压比r_(uth)随着τ_(s)的增大先减小后增大,当τ_(s)=5 k Pa时饱和粉土的r_(uth)最小。

循环荷载下饱和黄土的剪切特性与破坏模式

饱和黄土的破坏模式和剪切特性是分析黄土地基及其构筑物地震变形的基础,为了揭示循环荷载下黄土独特的强度衰减和变形劣化规律,本文开展了饱和黄土不排水动三轴试验,控制初始剪应力(q_(s))和循环剪应力(q_(c)),研究了不同初始应力状态下饱和黄土的动强度、孔压发展规律及破坏模式。试验结果表明:当q_(s)<q_(c)时,重塑和原状黄土试样表现为循环迁移型破坏,当q_(s)≥q_(c)时,重塑黄土试样表现为流动型破坏,而原状黄土试样则表现为塑性应变累积型破坏;黄土试样的循环应力比(R_(CS))、循环阻力比(R_(CR,10))随着初始剪应力比(R_(SS))的增大呈先增大后减小的趋势;循环迁移型和塑性应变累积型破坏在循环加载的初始阶段孔压上升迅速,孔压增长曲线分别呈“风琴”状和“喇叭”状,而流动型破坏的初始阶段孔压增长速率较慢,当到达某一振次后孔压突然增长,孔压增长曲线呈“镰刀”状。基于初始阶段孔压发展指标(K_(1-2))与初始应力状态(q_(s)/q_(c))提出了图表法,可用于预测循环荷载下饱和黄土的破坏模式。

血管力学生物学2023年度研究进展

心血管系统是一个以心脏为中心、血管为网络的力学系统,力学因素在调控心血管系统生理状态或病理进程中起到直接且关键的作用。冠心病、高血压和脑卒中等多种心血管疾病都有着相似的病理学基础,即由于血管功能失衡及损伤修复异常引起的血管重建。因此,研究力学因素如何产生生物学效应而导致血管重建,阐明心血管力学信号转导通路和力学调控途径,对于深入了解心血管活动和疾病发生的本质及其防治有重要意义。本文以力学刺激(环境)因素和关键力学响应分子为线索,总结2023年度血管力学生物学的最新研究进展。研究结果为进一步探讨力学因素在心血管疾病发病机制中的作用,寻找心血管疾病诊断的标志物和潜在靶标等提供了新思路。

Effect of Cyclic Loading on Cracking Behaviour of X-70 PipelineSteel in Near-Neutral pH Solutions

The cracking behaviour of X-70 pipeline steel in near-neutral pH solutions was studied under different modes of cyclic loading. The crack propagation process of X-70 pipeline steel under low frequency cyclic loading condition was controlled mainly by stress corrosion cracking （SCC） mechanism. Under mixed-mode cyclic loading, both higher tensile stress and shear stress made cracks easier to propagate. Applied cathodic potentials and high content of carbon dioxide in solutions also promoted the propagation of cracks. The propagation directions of cracks were different under different cyclic loading conditions. Under mode I （pure tensile stress） cyclic loading condition, cracks were straight and perpendicular to the tensile stress axis, while under mixed-mode 1/111 （tensile/shear stress） cyclic loading,cracks were sinuous and did not propagate in the direction perpendicular to the main tensile stress axis. Under the mixed-mode cyclic loading, cracks were much easier to propagate, suggesting that shear stress intensified the role of tensile stress. In addition, shear stress promoted the interaction between cracks, resulting in easier coalescence of cracks.

Stiffness Degradation of Undisturbed Saturated Soft Clay in the Yangtze Estuary Under Complex Stress Conditions

Stiffness degradation will occur due to the generation of accumulated pore pressure in saturated soft clays under cyclic loading. The soil static-dynamic multi-purpose triaxial and torsional shear apparatus in Dalian University of Technology was employed to perform different types of test on the saturated soft marine clay in the Yangtze Estuary. Undisturbed samples of the clay were subjected to undrained cyclic vertical and torsional coupling shear and cyclic torsional shear after three-directional anisotropic consolidation with different initial consolidation parameters. Investigated were the effects of the initial orientation angle of the major principal stress, initial ratio of deviatoric stress, initial coefficient of intermediate principal stress and continuous rotation of principal stress axes on the stiffness degradation. It is found that the degradation index decreases （or degradation degree increases） significantly with increasing initial orientation angle of the major principal stress and initial ratio of deviatoric stress. Compared with the effects of the initial orientation angle of the major principal stress and initial ratio of deviatoric stress, the effect of initial coefficient of intermediate principal stress is less evident and this trend is more clearly reflected by the results of the cyclic torsional shear tests than those of the cyclic coupling shear tests. At the same cycle number, the degradation index obtained from the cyclic torsional shear test is higher than that from the cyclic coupling shear test. The main reason is that the continuous rotation in principal stress directions during cyclic coupling shear damages the original structure of the soil more than the cyclic torsional shear does.Based on a series of experiments, a mathematical model for stiffness degradation is proposed and the relevant parameters are determined.

配筋齿槽装配式剪力墙拼缝水平相对滑移研究

装配式剪力墙拼缝界面的水平相对滑移对构件的力学性能有很大影响,以一片普通预制剪力墙为参照,开展新型配筋齿槽装配式剪力墙拼缝水平相对滑移研究.通过对两个装配式剪力墙试件进行低周反复加载试验,分析其裂缝分布情况、拼缝水平相对滑移曲线、荷载-位移曲线和钢筋应变等试验现象和数据,得到配筋齿槽装配式剪力墙拼缝水平相对滑移性能.最后通过分析配筋齿槽装配式剪力墙边缘约束构件区的纵向连接钢筋销键剪切应力与拼缝水平滑移以及竖向位移的关系,对边缘约束构件区的纵向连接钢筋销键剪切应力的影响因素和性能进行了总结.研究结果表明,配筋齿槽拼缝连接形式具有良好的抗剪切能力和抗滑移能力,配筋齿槽装配式剪力墙构件具备更良好的塑性变形能力和耗能能力;纵向连接钢筋销键剪切应力受水平滑移比和竖向位移比的影响,对装配式构件塑性发展、抗震性能以及内力传递造成不良影响.

Undrained dynamical behavior of Nanjing flake-shaped fine sand under cyclic loading

A series of dynamic behavior tests on Nanjing flake-shaped fine sand were performed by using the WFI cyclic triaxial apparatus made in England. The dynamic behaviors of Nanjing flake-shaped fine sand under different static deviator stress levels and cyclic stress ratios were studied. Through comparing the effective stress path under cyclic loading with static loading, the processes of liquefaction of saturated Nanjing flake-shaped fine sand with development of dynamic pore-water pressure, including the initial compact state, compression state and dilative state, were investigated. The variation of the shear stiffness with the number of cycles and cyclic strain was investigated by analyzing the secant shear modulus in each unload-reload loop of dynamic stress-strain relationship. And by means of the exponential function, the empirical equations of the relationship between secant shear modulus Gsec, shear modulus ratio Gsec/Gmax and cyclic strain ε were established based on series of test results. The results show that according to different combinations of static deviator stress and cyclic stress, two kinds of failure patterns with deviator stress reversal or no deviator stress reversal are observed in the samples tested in this series, including cyclic mobility and the failure of accumulation residual strain. In addition, the degradation of dynamic shear modulus is due to the development of vibration pore-water pressure and it is observed that the shear modulus reduces with the progressive number of cycles.

各向异性固结下饱和珊瑚砂的不排水循环反应特性

珊瑚砂是海洋成因的碳酸盐土,碳酸钙含量大于90%,由于其赋存条件特殊,波浪与地震作用导致珊瑚砂的循环应力状态异常复杂。为探究复杂静、动应力状态下饱和珊瑚砂的不排水循环反应特性,利用GDS空心圆柱扭剪仪对南沙珊瑚砂开展不同固结条件下90°跳转循环应力路径的系列不排水循环剪切试验。试验结果表明:各向异性固结条件下,超静孔压u_(e)和广义剪应变γ_(g)的增长速率随固结方向角α_(c)的增大而显著增加,而随固结比kc的增大而显著降低。在相同固结条件下,u_(e)和γ_(g)的增长速率随循环加载方向角α_(σ)的增大表现出先增后减的趋势。提出循环偏应力比q_(a)/S_(PT)(循环偏应力幅值q_(a)与不排水单调剪切试验得到的相变强度SPT之比)作为循环应力水平指标,不同的固结条件和循环加载路径下,饱和珊瑚砂的抗液化强度曲线有唯一性,且q_(a)/S_(PT)与失效循环次数N_(L)呈负幂函数关系。结合修正的SPT预测公式,以q_(a)/S_(PT)作为表征复杂静、动应力条件下抗液化强度指标更具简单且适用范围宽的优点。

不同循环应力路径下饱和珊瑚砂体应变的发展特征

地震、波浪引起排水或部分排水状态的饱和砂类土体应变的累积,会导致地表、海床和附近结构物的显著破坏,且饱和砂土排水循环加载的体应变增长与不排水循环加载的孔压增长存在定量的对应关系。通过对饱和珊瑚砂开展系列均等固结条件下排水循环剪切试验,探讨了初始相对密度Dr、循环应力路径及应力水平(CSR)对饱和珊瑚砂体应变发展特征的影响。试验结果表明,同一Dr和CSR下,残余体应变εvd,ir随短长轴比和在0°~90°时的椭圆倾角存在单调增长关系。不同Dr、循环应力路径和CSR下饱和珊瑚砂εvd,ir随循环次数N的发展曲线具有统一性,提出了两者的显式关系式。饱和珊瑚砂残余体应变极值(εvd,ir)u与εvd,ir-N关系曲线的收敛速度与Dr、循环应力路径和应力水平密切相关。引入单元体循环应力比USR来表征不同循环应力路径和CSR下饱和珊瑚砂的εvd,ir,发现同一Dr下,(εvd,ir)u与USR存在正相关线性关系,εvd,ir-N曲线的收敛参数CN1与USR存在正相关线性关系,CN2与USR存在负幂函数关系,即USR越大,εvd,ir-N曲线收敛越慢。相同USR下,(εvd,ir)u随Dr的增加而减小,εvd,ir-N曲线收敛速度随Dr的增加而变快。该研究提出的体应变模型为排水循环加载条件下残余体应变的发展机理提供了新的认识。

不同循环加载方式下饱和珊瑚砂的液化流动特性

循环荷载作用下饱和砂土的超静孔压累积是导致土体液化的原因,将可液化砂土视为流体是一种较新的液化研究思路。通过循环应力主轴90°跳转和连续旋转的均等固结、不排水循环剪切试验,探究了不同循环加载方式下饱和珊瑚砂的液化流动特性,发现以初始表观黏度η0规准的表观黏度比η/η0与超静孔压比ru的关系受循环应力路径的影响显著,η/η0随ru的增大而渐进衰退;而平均流动系数k随r_(u)的增长呈指数函数形式增大。循环应力比CSR(CSR=0.25~0.40)和循环加载频率f(f=0.1~1 Hz)对η/η0-ru和k-r_(u)关系的影响均不敏感。不论循环应力主轴90°跳转或连续旋转,发现表观黏度梯度和平均流动系数梯度均随ru的增大呈现出先增后减的特征,其反转点的ru≈0.9,可视为饱和珊瑚砂由固态向液态转变的相变孔压比ruth,以相应的相变平均流动系数k_(th)规准的k/k_(th)-r_(u)的所有试验数据点处于一个窄带内,且k/k_(th)随r_(u)增长服从指数函数关系。

复杂初始应力状态下松砂多向循环单剪特性

松砂极易液化,微小的应力状态变化也会影响其液化特性。基于多向循环单剪试验,采用松砂作为试验材料,开展不同静剪应力大小、方向和复杂剪切路径下的循环单剪试验,研究复杂初始应力状态下松砂循环单剪特性,得到以下主要结论:(1)随静剪应力比增大,试样剪应力峰值增大,第1个循环内孔隙水压力增量变大,试样更易液化;初始静剪应力大小对孔隙水压力的影响在剪切初期更显著。(2)随初始静剪应力和动剪应力主轴之间夹角增大,试样在X方向的剪应力峰值减小,试样孔隙水压力加速增长,在第1个循环以及最后1个循环内孔隙水压力增量变大,循环间差值增大,试样更易发生瞬时液化。(3)8字形剪切路径试样的应力-应变滞回圈面积最大,每个循环消耗能量最多,圆形剪切路径次之,直线剪切路径最小。复杂剪切路径会在剪切开始时诱发孔隙水压力的突然增加,加大各循环中孔隙水压力的增量,试样更易液化。(4)影响松砂液化因素的排序为:初始静剪应力与动剪应力夹角、剪切路径、初始静剪应力大小。

循环荷载作用下钙质砂动力特性三轴试验研究

为了保障南海岛礁交通基础设施的运营安全,有必要深入探究循环荷载作用下吹填钙质砂的动力特性。针对南海岛礁吹填钙质砂,采用GDS循环三轴仪开展了一系列排水循环三轴试验,定性和定量分析了钙质砂的残余应变、颗粒破碎、特征循环次数、临界循环应力比和失稳动剪应力等变量的变化规律,并提出了一个残余应变预测的经验模型。结果表明:钙质砂的临界循环应力比随围压增加而减小,二者关系可用幂函数表达,钙质砂的归一化失稳动剪应力随失稳循环次数增加而减小,二者满足对数函数关系。当循环应力比小于临界循环应力比时,钙质砂的残余应变随循环次数增加而增加;当循环应力比等于临界循环应力比时,钙质砂达到临界稳态,其临界稳态残余应变随临界稳态循环次数和围压增加而增加,但随临界循环应力比增加而减小;当循环应力比大于临界循环应力比时,钙质砂发生渐进失稳,其失稳残余应变随钙质砂的归一化失稳动剪应力增加而快速增加。钙质砂的稳态循环次数随围压和循环应力比增加而增加,而临界稳态和失稳循环次数分别随临界循环应力比和归一化失稳动剪应力增加而减小。对比分析钙质砂循环三轴试验结果与残余应变模型预测结果可知,推荐的经验模型能够描述多重因素作用下钙质砂的残余应变变化趋势和演化规律。

橡胶砂液化特性的动扭剪试验研究

为研究橡胶砂的液化特性,在不同的橡胶质量掺量、循环应力比、相对密实度、频率和有效围压工况条件下对橡胶砂进行动扭剪试验,分析橡胶砂的动力剪切应力-应变关系、动弹性模量和阻尼比的发展趋势.结果表明:橡胶颗粒质量掺量越高,橡胶砂越不易液化,广义剪切应变越小,橡胶砂越不易破坏;在橡胶颗粒掺量一定的情况下,试样破坏周次随循环应力比增大而减少;相对密实度和有效围压增大时,试样的剪切应变降低、抗液化能力增强,而剪切频率增大时,抗液化能力减弱;随着剪切应变和橡胶颗粒掺量的增加,试样弹性模量逐渐降低,阻尼比逐渐增大.

温升作用对深海沉积物静力特性及临界循环应力比的影响研究

针对取自中国南海西部海槽的深海黏土质沉积物,在不排水升温条件下开展了重塑试样的静动力学试验。探讨了温升作用对土体的不排水抗剪强度、孔压发展规律及临界循环应力比的影响。基于Yao的理论框架给出了不排水升温导致超孔压的表达式,讨论了不同温度条件下土体的不排水抗剪强度与临界循环应力比的关系。试验结果表明,不排水升温产生的超孔压导致土体的有效应力降低,削弱了土体的不排水抗剪强度,使土体展现出了拟似超固结土的力学特性;对于分级加载的循环剪切工况,累积应变的发展速度随温度的提高显著增加,但在剪切初期,温升作用抑制了累积孔压的发展,甚至导致负累积孔压的产生。以归一化累积孔压产生的分化标准作为判定门槛循环应力比的方法不能很好地适用于具有超固结特性的土体。建议综合考虑累积变形及孔压的发展规律讨论土体的界限循环应力比。整体来看,随着温度的升高土体的抗剪强度及临界循环应力比显著降低,在工程中应当引起充分重视。

不同循环应力路径下饱和珊瑚砂超静孔压增长的改进应力模型

为探究复杂循环加载下不同相对密实度D_(r)的珊瑚砂超静孔压u_(e)增长特性,利用GDS空心圆柱扭剪仪对饱和珊瑚砂进行了系列循环应力主轴90°跳转的均等固结不排水循环剪切试验。试验表明,循环应力路径、应力水平和D_(r)显著影响饱和珊瑚砂u_(e)增长模式;建立了适用于不同D_(r)和循环加载模式的超静孔压比r_(u)表达式,引入单元体循环应力比USR作为表征复杂循环应力路径的应力指标,给出了模型参数λ_(1)和θ基于USR和D_(r)的表达式。所建立的r_(u)表达式对复杂循环加载模式下不同D_(r)的饱和珊瑚砂r_(u)增长有较好的预测效果。文献中不同类型砂的试验数据独立验证了所建立的r_(u)表达式的适用性。

水平循环剪切作用下土工袋竖向变形特性试验研究

土工袋作为一种地基加固材料在工程中的应用越来越广泛,研究表明土工袋具有较高的阻尼比,能够有效地消能并阻隔地震波由场地向上部结构的传递。为了解土工袋在水平循环荷载作用下的竖向变形特性,开展了一系列土工袋组合体的水平循环剪切试验,研究了循环次数、竖向应力以及剪切应变幅值等加载特征对土工袋组合体竖向变形的影响,探讨了水平循环荷载作用下土工袋组合体的变形机制。结果表明:(1)土工袋组合体的累积竖向应变在试验初期变化较为显著,随着循环次数的增加,其累积竖向应变逐渐趋于稳定;(2)竖向应力和剪切应变幅值对土工袋组合体的竖向应变影响显著,随着竖向应力与剪切应变幅值的增大,其竖向应变也随之增加;(3)土工袋组合体在较大剪切应变幅值条件下开始出现层间滑移,试验初期土工袋组合体在层间滑移阶段竖向应变基本保持稳定,但是随着循环次数的增加,土工袋组合体层间界面反复摩擦使层间的咬合作用发生变化,靠近土工袋组合体层间界面的砂土颗粒在此过程中又进行了重新排列,最终导致试验后期土工袋组合体单次循环产生的竖向应变增量呈现出增长趋势。

颗粒破碎对于珊瑚砂液化特性的影响

利用GDS动三轴试验系统,对南海珊瑚砂进行了不同破碎度和不同动剪循环应力比下的等幅循环荷载试验,研究了破碎度,动剪循环应力比对南海珊瑚砂的液化特性的影响。试验结果表明:在一维固结试验条件下,随着固结围压的增大,珊瑚砂破碎度逐渐增大;对不同破碎度的珊瑚砂试样进行GDS动三轴试验,随着振动周次增加,在相同的破碎度下,随着动剪循环应力比的增加,试验孔压的发展速度逐渐加快,在相同的动剪循环应力比下,随着破碎度的增加,试样的孔压发展速度逐渐加快;饱和珊瑚砂动孔压的发展在动剪循环应力比为0.2的条件下的运用改进Booker模型拟合有较好的效果。

循环剪切荷载作用下岩石节理宏细观力学特性研究

借助颗粒流程序(PFC)建立了含有起伏节理的岩样模型,开展了4种法向应力下的循环剪切数值试验。根据试验结果,从宏观方面讨论了剪切应力-位移曲线在4个阶段的峰值应力变化特征。基于PFC软件内嵌的fish语言,编制了裂纹扩展过程监测模块,从细观角度描述了节理试样在循环剪切过程中裂纹扩展规律和破坏模式。经分析发现,裂纹主要集中在节理凸起处,节理起伏度和法向应力对试样的破坏模式有着重要影响。通过追踪微裂纹的数量对试样破坏规律进行量化分析,结果与裂纹示意图中得到的规律保持一致。循环剪切过程中,裂纹扩展相对于剪切应力增长来说,有滞后效应且对其有抑制作用,很好地揭示了节理试样在抵抗剪切荷载时的力学机制。