Effects of Confining Pressure Paths on Strength and Deformation of Calcareous Argillaceous Cemmented Sandstones

doi:10.12068/j.issn.1005-3026.2018.02.021

Abstract

Abstract: Considering the characteristics of short diagenetic age and high intensity mining of Jurassic weak cemented sandstone in western China， the conventional triaxial compression tests， different unloading rates of confining pressure in triaxial compression tests and multi-stage triaxial tests were conducted to study the effects of confining pressure path on the strength and deformation. The results show that: the peak strength， residual strength， peak strain， elastic modulus and Poisson ratio depend on the confining pressure strongly， and the cohesion and internal friction angle of the sandstones in western China are lower than those of other sandstones. As the confining pressure increases， the failure mode transits from single plane fracture to complex multi-fracture. During the loading process， the change of confining pressure can remarkably affect the strength and the deformation characteristic by restricting lateral dilatation and increasing the angle of internal friction. The effect of unloading and loading confining pressure path on the mechanical parameters can provide references for the optimization of mining velocity and the support design of the surrounding rock masses.

Key words: calcareous argillaceous cemented sandstone, confining unloading rate, multi-stage triaxial loading, peak strength, deformation

CLC Number:

TU458

ZHAO Yong-chuan， YANG Tian-hong， QIN Tao， WANG Hong. Effects of Confining Pressure Paths on Strength and Deformation of Calcareous Argillaceous Cemmented Sandstones[J]. Journal of Northeastern University Natural Science, 2018, 39(2): 254-259.

References

[1]Nasseri M H，Rao K S，Ramamurthy T.Failure mechanism in schistose rocks［J］.International Journal of Rock Mechanics and Mining Sciences，1997，34(3):205-219.
[2]Lion M，Skoczylas F，Ledésert B.Determination of the main hydraulic and poro-elastic properties of a limestone from Bourgogne，France［J］.International Journal of Rock Mechanics and Mining Sciences，2004，41(6):915-925.
[3]Badrul Alamn A K M，Niioka M，Fujii Y，et al.Effects of confining pressure on the permeability of three rock types under compression［J］.International Journal of Rock Mechanics and Mining Sciences，2014，65(1):49-61.
[4]Zhao Y C，Yang T H，Xu T，et al.Mechanical and energy release characteristics of different water-bearing sandstones under uniaxial compression［J/OL］.［2016-12-05］.http://journals.sagepub.com/doi/abs/10.1177/105678951 7697472.
[5]Dai B，Zhao G Y，Dong L J，et al.Mechanical characteristics for rocks under different paths and unloading rates under confining pressures［J/OL］.［2016-07-15］.https://www.hindawi.com/journals/sv/2015/5787481/.DOI:10.1155/2015/578748.
[6]He M C，Miao J L，Feng J L.Rock burst process of limestone and its acoustic emission characteristics under true-triaxial unloading conditions［J］.International Journal of Rock Mechanics and Mining Sciences， 2010，47(2):286-298.
[7]Youn H，Tonon F.Multi-stage triaxial test on brittle rock［J］.International Journal of Rock Mechanics and Mining Sciences，2010，47(4):678-684.
[8]Taheri A，Tani K.Developing a damage model to simulate multiple-step loading triaxial compression tests in rocks［J］.Geotechnical and Geological Engineering，2013，31(2):541-556.
[9]Tang L S，Sang H T，Song J，et al.Mechanical model for failure modes of rock and soil under compression［J］.Transaction Nonferrous Metal Society of China，2016，26(10):2711-2723.
[10]尤明庆.岩样三轴压缩的破坏形式和Coulomb强度准则［J］.地质力学学报，2002，8(2):179-185.(You Ming-qing.Destroy character and Coulomb criterion of rock specimen in triaxial compression［J］.Journal of Geomechanics，2002，8(2):179-185.)
[11]尹光志，李小双，赵洪宝.高温后粗砂岩常规三轴压缩条件下力学特性试验研究［J］.岩石力学与工程学报，2009，28(3):598-604.(Yin Guang-zhi，Li Xiao-shuang，Zhao Hong-bao.Experimental investigation on mechanical properties of coarse sandstone after high temperature under conventional triaxial compression［J］.Chinese Journal of Rock Mechanics and Engineering，2009，28(3):598-604.)
[12]陶振宇，陈铁民.岩石的基本摩擦角及高压摩擦特性［J］.科学通报，1991，36(20):1567-1569.(Tao Zhen-yu，Chen Tie-min.Properties of rock basic friction angle and high friction［J］.Chinese Science Bulletin，1991，36(20):1567-1569.)
[13]谢和平，周宏伟，刘建锋，等.不同开采条件下采动力学行为研究［J］.煤炭学报，2011，36(7):1067-1074.(Xie He-ping，Zhou Hong-wei，Liu Jian-feng，et al.Mining induced mechanical behavior in coal seams under different mining layouts［J］.Journal of China Coal Society，2011，36(7):1067-1074.)

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