共查询到19条相似文献,搜索用时 187 毫秒
1.
2.
循环剪切吸水条件下饱和砂土的应力应变规律 总被引:1,自引:0,他引:1
在实际土工抗震边值问题中,饱和砂土在许多情况下并非处于完全不排水条件,可能由于土性等因素的不同而出现各异的排渗条件。排水条件对土体的动力应力应变响应有较大影响,本文基于新开发的孔隙水注入控制系统,进行了循环剪切条件下饱和砂土吸水试验,研究了剪切吸水对土体动力特性的影响规律。通过试验发现:剪切吸水条件下砂土的抗液化强度较不排水条件下降低,同样的循环剪切条件下轴向应变发展更大;试样的抗液化强度降低和轴向应变增加程度随剪切吸水率的增大而增加。基于对饱和砂土体变规律的已有研究,本文初步解释了剪切吸水条件下饱和砂土应力应变特性规律的物理实质。 相似文献
3.
《地震工程与工程振动》2015,(6)
给出了基于颗粒离散元模拟饱和砂土不排水循环三轴试验的模型和方法。基于计算结果,分析了模拟试样在循环荷载下的流动性及主要特征。结果表明,数值模拟得到的循环荷载下饱和砂土宏观动力响应与室内动三轴试验结果基本一致,控制应变幅值和有效固结压力对试样宏观动力响应的影响规律符合已有的认识;控制应变幅值对模拟试样的平均流动系数-孔压比关系曲线基本无影响,模拟试样的流动性演变与孔压状态相关;有效固结压力限制试样流动性的增长。验证了基于颗粒流细观模拟方法分析饱和砂土流动性的可行性。 相似文献
4.
研究交通循环荷载作用下路基软黏土的长期沉降和动力力学性质对路基设计具有重要意义。本文通过GDS动三轴实验,研究(不排水条件下)振动波形、排水条件以及动应力比三因素对于软黏土动应变和动孔压的影响。试验结果显示:排水条件对饱和软黏土的动应变和动孔压影响最大,在部分排水条件下动孔压逐渐消散,动应变迅速发展。振动波形对软黏土动应变和动孔压影响较大,单向纯压半正弦波作用下软黏土的动应变和动孔压较容易达到最大值。在较少的振次内动应力比对孔压影响较大,但在归一化的孔压模型中,动应力比对孔压影响较小。通过以上分析,本文建立包含循环振次和纯压因素的孔压增长模型。 相似文献
5.
不同地域的软黏土表现出不同的动力学特性,针对舟山地区海相软黏土,采用Wille动三轴仪开展了一系列不排水三轴试验,研究了不同加载频率及循环应力比对软黏土的动应力-应变-孔压及软化指数等的影响规律。结果表明:低频荷载的应力-应变滞回曲线对应的面积较大且曲线趋势更倾向于应变轴,随着循环次数的增加土体的软化程度明显增加(软化指数减少),且在高循环应力比下产生较大的累积塑性应变和残余动孔压;在低频较大循环振次和高频荷载作用下,不仅需要关注循环应力比CSR的影响,也需要进一步分别关注围压和轴向偏应力各自数值不同所导致的土体累积塑性应变、残余动孔压的变化;降低循环应力比可以显著减少不同频率荷载对软黏土地基动力特性的影响。此外,实验所测的累积塑性应变和残余动孔压分别采用相关修正模型拟合,取得了一致的拟合结果。该研究将为舟山海相软黏土的工程应用提供参考依据。 相似文献
6.
7.
依据等效黏弹性理论与蠕变理论,建立了描述一般应力状态饱和软土不排水循环应力应变响应的拟动力本构关系。该关系包括三个基本参数:循环剪切模量,阻尼比与增量循环累积应变。利用循环剪切模量与阻尼比随土单元八面体剪应变的变化描述循环荷载作用下软土的不排水循环应变,依据Mises蠕变势函数与正交流动法则确定循环累积应变增量。通过饱和软土不固结不排水循环三轴压缩试验确定这些变化关系。按确定出的参数预测循环三轴拉伸与循环扭剪试验结果。预测出的循环拉伸试验剪切模量和阻尼比随八面体剪应变的变化与试验结果吻合。对于循环扭剪试验,当循环偏应力与静偏应力方向一致时,预测出的循环累积应变随循环次数的变化与试验结果基本一致;当循环偏应力与静偏应力作用方向不一致时,预测出的循环累积应变与试验结果相比偏小。 相似文献
8.
9.
依据等效黏弹性理论与蠕变理论,建立了描述一般应力状态饱和软土不排水循环应力应变响应的拟动力本构关系。该关系包括三个基本参数:循环剪切模量,阻尼比与增量循环累积应变。利用循环剪切模量与阻尼比随土单元八面体剪应变的变化描述循环荷载作用下软土的不排水循环应变,依据Mises蠕变势函数与正交流动法则确定循环累积应变增量。通过饱和软土不固结不排水循环三轴压缩试验确定这些变化关系。按确定出的参数预测循环三轴拉伸与循环扭剪试验结果。预测出的循环拉伸试验剪切模量和阻尼比随八面体剪应变的变化与试验结果吻合。对于循环扭剪试验,当循环偏应力与静偏应力方向一致时,预测出的循环累积应变随循环次数的变化与试验结果基本一致;当循环偏应力与静偏应力作用方向不一致时,预测出的循环累积应变与试验结果相比偏小。 相似文献
10.
通过GDS动三轴设备对赣南红黏土进行了一系列排水条件下的大次数循环试验,研究不同循环应力比、固结应力比及围压对赣南红黏土累积变形特性的影响。结果表明:在不同固结应力比、固结压力和循环应力比条件下,红黏土的累积应变都呈现出先迅速累积,后增长变缓,最终稳定的趋势;在一定的循环次数之后,不同初始固结应力和不同初始应力比条件下累积应变与循环次数之间的变形规律呈现为线性关系,且初始固结应力和初始固结应力比越小,其线性相关性越好;不同循环应力比下赣南红黏土的平均累积应变速率与循环次数之间也呈现出明显的线性关系。此外,基于以上关系建立了赣南红黏土在长期循环荷载作用下的累积变形预测模型,并通过对比验证了该模型的可行性。 相似文献
11.
Small strain shear modulus Gmax is an essential parameter in soil dynamics, and it is usually estimated based on the Hardin and Richart equation. However, many previous researches on sands have indicated that the Hardin and Richart equation does not consider the influences of cyclic loading history on Gmax. In this paper, effects of cyclic loading history on Gmax of saturated clays under undrained conditions are studied using a combination device of piezoelectric-ceramic bender element system and cyclic triaxial apparatus. The dynamic pre-loading includes both relatively high amplitudes of cyclic stresses and cyclic strains. Gmax without cyclic loading history is also investigated for the comparison purpose. Test results show that, at the same effective stress, both cyclic strain history and cyclic stress history will induce reduction of Gmax compared to the corresponding Gmax values with non-cyclic loading effects. In strain-controlled tests, the reduction of Gmax is slight and relatively stable; while in stress-controlled tests, the reduction of Gmax increases suddenly and remarkably when the effective stresses degrade to a certain degree. The comparison between double amplitude axial strain and residual excess pore water pressure behaviors show that the remarkable reduction of Gmax can demonstrate the cyclic failure of saturated clays. 相似文献
12.
通过砂土的一系列动三轴实验,研究不规则地震荷载作用下与定次数等幅荷载作用下土体变形间的关系,给出砂土相对密实度对二者间关系的影响规律。结果表明:真实地震荷载下土的变形发展与等幅正弦荷载明显不同,应变发展时程的形态主要受地震动的形态控制;应变比C与砂土相对密度间关系具有规律性,随相对密度增大而降低,若采用以20周作为标准作用次数、0.65倍地震波峰值为等幅荷载代替不规则的地震荷载,修正真实地震应力下的残余变形,其应变比C随砂土密实度的增大而减小。同时,冲击型荷载的应变比C`要远大于振动型荷载。 相似文献
13.
As a new artificial geo-material, lightweight soil is an ideal countermeasure to solve many geotechnical problems in soft ground by reducing upper load, and Lightweight Sand–EPS Beads Soil (briefly as LSES) is a typical representative. Generally used as backfill, which may bear earthquake loading or traffic loading, the behaviors of LSES under dynamic loading are worth to pay much attention on, though there are few relative studies about this at present. Based on laboratory cyclic triaxial test data presented in this study, a united framework is tried to set up, in which deformation and strength of LSES can be integrated by failure cycle number Nf that corresponds to the complete degradation of LSES structure. This framework describes both the development process of cyclic deformation and dynamic failure criteria in the state as the structure cannot afford further tension. Meanwhile, cyclic stress–strain relationships and Modulus Reduction Curves for LSES with different mixture ratios are also discussed. All distinct behaviors of LSES are considered to arise from its bond-dominated structure, which controls the two types of modulus reduction characteristics and brittle failure of LSES under cyclic loading. 相似文献
14.
Upon cyclic loading, particle breakage of constituent granular materials occurs when the resulting local stresses exceed their strength, which has a significant influence on the deformation of the embankment, foundation and pavement structures. In this study, the artificially crushable materials were tested to investigate the particle breakage properties of these structures when subjected to drained cyclic triaxial loading. Twelve sets of samples were tested at the confining pressures of 100, 125, 150 and 175 kPa and a frequency of 1.0 Hz using a GCTS triaxial system. The cyclic test results indicate that at the same confining pressure, the residual volumetric strain increases with decreasing maximal deviatoric stress qmax at a given ratio of the number of cycles (N) to the number of cycles of failure (Nf). The cumulative crushing ratio Rcc decreases with increasing qmax, leading to a reduction in Nf. The internal frictional angle decreases with increasing Rcc, and Rcc increases with increasing Nf. Furthermore, the confining pressure, maximal cyclic deviatoric stress and N have significant influences on the degree of particle breakage, which leads to volumetric contraction during the cyclic loading process. Finally, the resilient modulus at failure increases linearly with increasing Rcc. 相似文献
15.
在三轴压缩下大理岩循环加载实验的初步研究 总被引:7,自引:1,他引:7
在围压10、50、100和200MPa,应变率5×10-5/s和室温条件下,采用山东掖县大理岩岩样,在800t高温高压伺服三轴流变仪上进行了连续加载和循环加载实验.对岩样的残余强度和弹性模量的变化等问题进行了初步研究.得出:在低围压下(<100MPa),残余强度与超过极限强度后的循环加载次数有关;超过极限强度后加载弹性模量随着非弹性应变的增加而减小,并趋于一个极限值.在高围压下(≥100MPa),残余强度几乎与超过极限强度后的循环加载次数无关;超过极限强度或者产生应变强化后加载弹性模量几乎不随非弹性应变的增加而减小. 相似文献
16.
为探究重复循环荷载作用下含水率、固结压力对原状黄土动力特性、变形性状的影响规律,利用英国GDS双向动态三轴试验系统模拟交通荷载,对海东地区原状黄土进行动三轴试验研究。试验结果表明:单一重复循环动荷载作用下,在加载初期,海东地区原状黄土的轴向动应变随着循环次数的增大急剧增加,后期缓慢增加至趋于稳定,即发生应变硬化现象。在加载初期,含水率、固结压力对原状黄土的轴向动应变无明显影响,当循环次数N>400时,原状黄土的轴向动应变随含水率的升高而增加,随固结压力的增大而减小。动剪切模量随循环次数的增加出现先减小后增加再减小的变化,随含水率的升高有较大幅度的降低。动阻尼比随循环次数的增加先增加后减小,随含水率的升高而增大。表明海东地区原状黄土所具有的大孔隙架空结构使其在重复循环荷载作用下易发生振动变形。 相似文献
17.
To investigate the coupling effects of cyclic deviator stress and cyclic confining pressure on the deformation behavior of natural soft clay under partially-drained conditions, a series of one-way cyclic triaxial tests with and without cyclic confining pressure were carried out. Test results show that, at the same amplitude of cyclic deviator stress, the increase of cyclic confining pressure amplitude will accelerate the accumulation of both permanent volumetric and axial strain significantly. The comparison between test results for different amplitudes of cyclic confining pressure shows that tests with a cyclic confining pressure corresponding to a stress path of ηampl=pampl/qampl=1 lead to a 1.4 times larger permanent volumetric strain and a 1.2 times larger permanent axial strain compared to the conventional cyclic triaxial tests with constant confining pressure (ηampl=1/3). In case of ηampl=2 the permanent strains are found to be even 2.0 or 1.5 times larger compared to the standard tests. Finally, an empirical formula is proposed for the prediction of permanent axial deformations of natural soft clays under partially-drained conditions, considering the effects of cyclic confining pressure. 相似文献
18.
This paper focuses on using high-frequency GAP-SENSORs (GSs), accelerometers, and load cells in a laminar shear box (LSB) filled with loose Toyoura sand to understand the effects of impact loads and cyclic shaking at 1-G on soil properties. The shear wave velocity at small strain (Vs) was calculated directly from first arrival reference using displacement time-history of two GSs under impact loading. Moreover, from first peak using the reduced deformation amplitude technique, damping ratio was calculated. In addition, shaking table tests were performed under harmonic loading with amplitude of acceleration inside the model ground varying from 0.02 g to 1 g. The frequencies of excitation varied from 1 Hz to 10 Hz. GSs and inside accelerometers were used to directly measure the outside lateral deformation and shear stress at different elevations of LSB, respectively. Results show that the shear modulus (G) and the damping ratio (D) behavior of model sand are generally consistent with the behavior presented by similar tests using only accelerometers. In addition, damping ratio increases as frequency loading increases. Characteristic changes in two shear stress components in shaking loading conditions were also investigated using high precision inside load cells. 相似文献
19.
Subgrade soils of traffic infrastructures are subjected to large numbers of load applications at a stress level below their shear strength. It is therefore of great practical relevance to study the deformation behavior of soft clay under long-term cyclic loading. In this study, a series of monotonic triaxial tests and long-term cyclic (50,000 cycles) triaxial tests have been carried out to investigate the undrained deformation behavior of undisturbed soft clay from Wenzhou, China. The stress–strain hysteretic loop, resilient modulus and permanent strain of the tested samples were found significantly dependent on CSR and confining pressure. With an increase of CSR and confining pressure, the resilient modulus decreases more significantly with increasing number of cycles and the accumulation rate of permanent strain increases. Furthermore, the shape of the stress–strain hysteretic loop almost remains unchanged and the resilient modulus tends to a steady value after a large number of cycles. Based on the experimental results, two equations are established for the prediction of long-term resilient modulus and permanent strain. Finally, a new critical value of 0.65 is suggested for CSR. When CSR>0.65, the resilient modulus for large number of cycles is reduced to a so called “asymptotic stiffness” and the accumulation rate of permanent strain significantly increases. 相似文献