华南地震

为了研究含水率变化对成层状风化花岗岩边坡稳定性的影响，进行了一系列单调直剪试验。设置四种含水率（13%、17%、21%和25%）和三种干密度（ρd1、ρd2、ρd3），分析不同干密度下含水率对花岗岩残积土-全风化花岗岩界面剪切特性的影响。试验结果表明：在低含水率、高干密度和低竖向应力下，界面剪应力易发生剪切软化，反之，更易发生剪切硬化；含水率越高，最大剪胀量越小，且干密度越大，最大剪胀量受含水率变化的影响越小；含水率升高会大幅降低界面抗剪强度，且干密度越大、竖向应力越小，界面抗剪强度随含水率的变化率越大。

In order to study the effect of rainfall on the stability of weathered granite layered slope， a series of monotone direct shear tests were carried out. Four kinds of water content （13%， 17%， 21% and 25%） and three kinds of dry density were set to analyze the effect of water content on the shear characteristics of granite residual soil and completely weathered granite interface shear behaviour. The experimental results indicate that the shear stress of the interface is prone to shear softening under low water content， high dry density and low normal stress，and otherwise，shear hardening is more likely to occur. The maximum dilatancy decreases as the increase of water content. And the larger the dry density is，the less the effect of water content on the maximum dilatancy is. The increase of water content significantly reduces the interfacial shear strength，and the greater the dry density， the smaller the normal stress，and the greater the attenuation coefficient of interfacial shear strength.

引言
1 试验材料与方法
2 试验结果
3 结论

图1 风化花岗岩边坡示意图Fig.1 Schematic diagram of weathered granite slope

表1 土样物理参数Table 1 Physical parameters of soil samples

表2 试验方案Table 2 Test scheme

图2 界面剪切应力—位移特征曲线Fig. 2 Shearing stress-displacement characteristic curve of interface

图3 界面竖向位移-剪切位移关系Fig.3 Vertical displacement-shearing displacement curve of interface

图4 界面最大剪胀量与含水率、竖向应力和干密度的关系Fig.4 Relationship betweer the maximum dilatancy of interface and water content，vertical stress and dry density

图5 界面抗剪强度与含水率、竖向应力和干密度的关系Fig.5 Relationship between interfacial shear strength and water content，vertical stress and dry density

表3 界面抗剪强度随含水率的变化率Table 3 Change rate of interfacial shear strength with water content

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备注

引言

1 试验材料与方法

2 试验结果

3 结论

期刊信息