滑带土含水率与力学参数关系试验研究

齐剑峰; 张成兵; 宋雪琳; 李铎

doi:10.3969/j.issn.1001-5485.2013.07.018

长江科学院院报 >

2013 , Vol. 30 >Issue 7: 91 - 94

DOI: https://doi.org/10.3969/j.issn.1001-5485.2013.07.018

岩土工程

滑带土含水率与力学参数关系试验研究

齐剑峰 ,
张成兵 ,
宋雪琳 ,
李铎

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1.河北省水资源可持续利用与开放重点实验室, 石家庄 050031;
2.河北省地矿局第四水文工程地质队, 河北沧州 061000

齐剑峰(1975-),男,河南太康人,副教授,博士,主要从事土力学基本理论、地质灾害及其防治等方面的研究,(电话)15833311974(电子信箱)jianfengluck@163.com。

收稿日期: 2012-10-03

修回日期: 2013-07-03

网络出版日期: 2013-07-03

基金资助

973专项(2010CB428805-1);国家科技支撑项目(2006BAC04B01);国家大坝安全工程技术开放基金(NDSKFJJ1201)

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Experimental Study on the Relation Between Water Content and Mechanical Properties of Soils in Sliding-Zone

QI Jian-feng ,
ZHANG Cheng-bing ,
SONG Xue-lin ,
LI Duo

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1.Hebei Provincial Open Laboratory of Sustained Development and Utilization of Water Resource, Shijiazhuang 050031, China;
2.The Fourth Team of Hydro-Engineering of Hebei Provincial Bureau of Geo-exploration Mineral Development, Cangzhou 061000, China

Received date: 2012-10-03

Revised date: 2013-07-03

Online published: 2013-07-03

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摘要

为研究降雨型滑坡滑带土力学性质的变化规律,通过三轴剪切试验,在不同含水率下对某滑坡滑带土的应力-应变关系、抗剪强度与变形模量以及强度指标进行了初步研究。研究表明,含水率对滑带应力-应变关系发展模式影响显著。当含水率小于塑限时,应力-应变关系的发展模式为弹性变形→应变硬化→出现峰值→应变软化,出现剪切破坏面;而当含水率大于塑限时,应力-应变关系发展模式基本上是应变硬化,出现鼓胀破坏。随含水率增大,滑带土抗剪强度降低,可分为3个阶段:塑限含水率以前,抗剪强度变化不明显;塑限含水率至17%(液限与塑限含水率的平均值附近)时,抗剪强度下降速率最大;随后变缓。随含水率增大,滑带土黏聚力降低,近似符合双线性关系。

关键词： 滑带土; 含水率; 应力-应变关系; 破坏模式; 强度指标

本文引用格式

齐剑峰 , 张成兵 , 宋雪琳 , 李铎 . 滑带土含水率与力学参数关系试验研究[J]. 长江科学院院报, 2013 , 30(7) : 91 -94 . DOI: 10.3969/j.issn.1001-5485.2013.07.018

Abstract

To research the mechanical properties of soil in the sliding zone of rainfall induced landslide, we investigated the stress strain relation, shear strength index and initial deformation modulus by triaxial shear tests. The results indicated that the water content has remarkable impact on the development mode of stress strain relations. When the water content is smaller than the plastic limit, the stress strain relation experienced a process from elastic deformation to strain hardening, to peak value emergence, then to strain softening, and finally to shear failure surface; while when the water content is larger than the plastic limit, the mode of strain stress relations generally developed from strain hardening swell at strength decreases, which can be divided into three phases: when the water content is smaller than the plastic limit, the variation of shear strength is not obvious; when the plastic limit is 17% (in the vicinity of the average value of liquid limit and plastic limit), the shear strength reduces most rapidly; and afterwards, the decrease of shear strength slows down. With the increase of water content, the cohesion decreases in an approximate bilinear relation.

Key words： sliding zone soil; water content; stress strain relation; failure mode; strength index.

参考文献

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