从变形、水量变化和强度三方面验证非饱和土的两个应力状态变量

张龙; 陈正汉; 周凤玺; 孙树国; 扈胜霞; 姚志华

doi:10.11779/CJGE201705015

从变形、水量变化和强度三方面验证非饱和土的两个应力状态变量 English Version

张龙^{1, 3},
陈正汉^1,2, ,,
周凤玺¹,
孙树国²,
扈胜霞⁴,
姚志华⁵

1. 兰州理工大学土木工程学院,甘肃兰州 730050;
2.中国人民解放军后勤工程学院,重庆 401331;
3. 机械工业勘察设计研究院,陕西西安 710043;
4. 延安大学建筑工程学院,陕西延安 716000;
5. 空军工程大学机场建筑工程系,陕西西安 710038

基金项目: 国家自然科学基金项目（11272353,11672330,51309199,51509257）

详细信息

作者简介:
张龙（1988- ）,男,河北藁城人,硕士研究生,主要从事非饱和土与特殊土力学研究。E-mail: 709194126@qq.com。

通讯作者:
陈正汉，E-mail：chenzhenghan47@163.com

中图分类号: TU443
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出版历程
- 收稿日期: 2016-05-04
- 发布日期: 2017-05-24

Verification of rationality of two stress state variables of unsaturated soil from deformation, moisture change and strength

1. School of Architecture and Construction of Lanzhou University of Technology, Lanzhou 730050, China;
2. Logistic Engineering University of PLA, Chongqing 401331, China;
3. China JK Institute of Engineering Investigation and Design, Xi'an 710043, China;
4. School of Architecture and Civil Engineering of Yan'an University, Yan'an 716000;
5. School of Airport Construction Project of Air Force Engineering University, Xi'an 710038, China

摘要

摘要: 为了验证非饱和土两个应力状态变量的合理性,对常规非饱和土三轴仪进行了改进,采用3个压力-体积控制器分别控制孔隙水压力、内室压力和外室压力,提高了量测体变和含水率的精度;用加荷器施加轴向荷载,可以方便地控制偏应力。在笔者前期用各向等压试验验证非饱和土的两个应力状态变量的基础上,使用改进的非饱和土三轴仪和重塑Q₃黄土做了两类验证试验：第一类是两组控制净围压、偏应力和吸力的固结不排水剪切试验,第二类是3组控制净围压和吸力的固结排水剪切试验。在第一类试验中,等值改变（增加或减少）总围压、孔隙水压力和孔隙气压力而保持净围压、吸力和偏应力本身不发生变化,发现试验过程中土样的体积变化和含水率变化均非常小,可以忽略不计。第二类试验的每一组包含两个控制净围压和吸力分别相同的固结排水剪切试验,其中一个试样在固结完成后直接进行排水剪切试验,另一个试样在固结完成后等值增加总围压、孔隙水压力和孔隙气压力而保持净围压和吸力本身不发生变化的条件下进行排水剪切试验,发现二者的抗剪强度、剪切过程中的体积变化、排水量和广义剪应变都分别十分接近,可以认为两两相等。研究结果从变形（包括体应变和剪应变）、水量变化和强度3个方面说明描述非饱和土的两个应力状态变量是合理的,进一步夯实了非饱和土力学的应力理论基础,为非饱和土的两个应力状态变量理论提供了牢靠的试验依据。
- 非饱和土 /
- 应力状态变量 /
- 重塑黄土 /
- 偏应力 /
- 抗剪强度
Abstract: In order to verify the rationality of two stress state variables of unsaturated soil, the conventional triaxial apparatus is improved: three pressure-volume controlles are employed to respectively control the pore water pressure, inner and outer chamber pressures so as to improve the measurement precision of volume change and water content; and the axial load by loading derice can conveniently control the deviator stress. Based on the previous verified results of isotropic tests by the authors, the improved unsaturated soil triaxial apparatus and remolded Q3 loess are used to conduct two types of experiments: one is two groups of consolidation undrained shear tests under the net confining pressure, deviator stress and suction, and the other is three groups of consolidation drained shear tests under the net confining pressure and suction. In the first type of tests, with the equivalent change (increase or decrease) of the confining pressure, pore water pressure and pore air pressure, and without the change of the net confining pressure, suction and deviator stress, it is found that the volume change and moisture change are very small and can be neglected. In the second type of tests, each group contains two consolidation drained shear tests with the same net confining pressure and suction. Among the tests, one is that after the completion of the consolidation, the direct drained shear tests are performed; the other is that after the completion of the consolidation, with the equivalent increase in the total confining pressure, pore water pressure and pore pressure and without the change of the net confining pressure and suction, the drained shear tests are performed. It is found that their shear strengths, volume changes in the shearing process, generalized shear strains and drainages are very close and can be considered to be equal. The use of two stress state variables to describe the stress state of unsaturated soil is reasonable in terms of deformation, moisture change and strength, which consolidates the mechanics theory of unsaturated soil and provides a reliable experimental basis for the theory of two stress state variables of unsaturated soil.
- unsaturated soil /
- stress state variable /
- remolded loess /
- deviator stress /
- shear strength

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参考文献(14)

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