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GUO Bing-bing, CHEN Guo-xiang. Experimental Study on Relationship Between Water Content and Shear Strength Parameters of Soft Rock in Coal Mine[J]. Safety in Coal Mines, 2013, 44(12): 4-6,7.
Citation: GUO Bing-bing, CHEN Guo-xiang. Experimental Study on Relationship Between Water Content and Shear Strength Parameters of Soft Rock in Coal Mine[J]. Safety in Coal Mines, 2013, 44(12): 4-6,7.
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Experimental Study on Relationship Between Water Content and Shear Strength Parameters of Soft Rock in Coal Mine

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  • Published Date: December 19, 2013
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  • This paper mainly studies the relationship between water content and shear strength and shear strength parameters by direct shearing with undisturbed samples and remodeling samples. The research shows that shear strength decreases exponentially with the increase of water content and the relationship between water content and cohesion and internal friction angle can be expressed by exponential function in undisturbed samples. The influence of water content on cohesion is more significant than internal friction angle. Cohesion increases at first, then decreases with the increase of water content and internal friction angle is in a state of unstable fluctuation in remodeling samples. The conclusion has been applied to soft rock slope treatment in east slope in some open-pit coal mine.
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    • References (7)
  • [1]
    何满潮,景海河,孙晓明.软岩工程地质力学研究进展[J].工程地质学报,2000,8(1):46-62.
    [2]
    赵丽明, 潘启新, 王宏伟,等.煤矿软岩巷道支护技术研究[J].中国矿业,2008,17(4):79-82.
    [3]
    刘长武,陆士良.泥岩遇水崩解软化机理的研究[J].岩土力学,2000,21(1):28-31.
    [4]
    周翠英,邓毅梅,谭祥韶,等.饱水软岩力学性质软化的试验研究与应用[J].岩石力学与工程学报,2005,24(1):34-38.
    [5]
    梁斌,莫凯.不同含水率下重塑红黏土抗剪强度特性的研究[J].山西建筑,2010,36(4):101-102.
    [6]
    张存根,张怀静.粉质粘土含水量与抗剪强度参数关系的试验研究[J].华北科技学院学报,2011,8(2):27-29.
    [7]
    刘海霞,王莉,邢姣秀.重塑非饱和土抗剪强度指标与含水状态变化的关系[J].黑龙江科技学院学报:自然科学版,2006,20(1):29-31.
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