动载下岩石边坡稳定性研究
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摘要
采用拟动力法分析了岩石边坡在动载力作用下的极限承载力。采用Hoek-Brown强度准则描述岩体的抗剪特性,并得到等效的Mohr-Coulomb强度参数。基于离散法构建破坏模型,在此基础上,通过极限分析上限法推导并计算得到了极限承载力的上限解。分析表明,岩石本身强度参数对其稳定性影响比较明显;而水平动载加速度系数的影响明显大于竖直动载加速度系数的影响。初始时间差和岩体放大系数对极限承载力有显著影响。因此,在存在坡顶荷载的边坡稳定性设计中,应考虑因边坡地形等因素导致的动载作用放大的影响。
A pseudo-dynamic approach was adopted to analyze the ultimate bearing capacity of slope under dynamic loading. The Hoek-Brown yield criterion was used to describe the shear resistance of rock mass and the equivalent Mohr-Coulomb strength parameter was obtained. A failure mode was constructed based on the discretization technique and the upper-bound solution of ultimate bearing capacity of rock slope was derived based on upper-bound theory of limit analysis. It is shown that the strength parameter of rock has brought an obvious impact on its stability,and horizontal dynamic load acceleration coefficient obviously has brought more impact than vertical dynamic load acceleration coefficient. While the initial time difference and amplification factor of rock mass have brought remarkable impact on the ultimate bearing capacity of slope. It is concluded that the effect by amplification of dynamic load action caused by slope topography shall be taken into consideration in the stability design for the slope with load on its crest.
A pseudo-dynamic approach was adopted to analyze the ultimate bearing capacity of slope under dynamic loading. The Hoek-Brown yield criterion was used to describe the shear resistance of rock mass and the equivalent Mohr-Coulomb strength parameter was obtained. A failure mode was constructed based on the discretization technique and the upper-bound solution of ultimate bearing capacity of rock slope was derived based on upper-bound theory of limit analysis. It is shown that the strength parameter of rock has brought an obvious impact on its stability,and horizontal dynamic load acceleration coefficient obviously has brought more impact than vertical dynamic load acceleration coefficient. While the initial time difference and amplification factor of rock mass have brought remarkable impact on the ultimate bearing capacity of slope. It is concluded that the effect by amplification of dynamic load action caused by slope topography shall be taken into consideration in the stability design for the slope with load on its crest.
引文
[1]Yang X L.Seismic displacement of rock slopes with nonlinear HoekBrown failure criterion[J].International Journal of Rock Mechanics and Mining Sciences,2007,44(6):948-953.
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[3]黄睿,夏唐代,钟丽娜,等.地震作用下挡土墙抗滑动稳定性的拟动力分析[J].中南大学学报(自然科学版),2014(9):3186-3192.
[4]Choudhury D,Nimbalkar S S.Pseudo-dynamic approach of seismic active earth pressure behind retaining wall[J].Geotechnical and Geological Engineering,2006,24(5):1103-1113.
[5]Choudhury D,Nimbalkar S.Seismic passive resistance by pseudo-dynamic method[J].Géotechnique,2005,55(9):699-702.
[6]罗根传,胡庆国,谭积青.基于极限平衡法与强度折减法的高边坡过程稳定性分析[J].矿冶工程,2013,33(2):14-17.
[7]刘秀军,贺建清.径向条分极限分析法在土坡稳定性分析中的应用[J].矿冶工程,2011,31(2):12-15.
[8]孙志彬,潘秋景,杨小礼,等.非均质边坡上限分析的离散机构及应用[J].岩石力学与工程学报,2017,36(7):1680-1688.
[9]杨小礼.岩石极限分析非线性理论及其应用[J].中南大学学报(自然科学版),2009,40(1):225-229.
[10]杨小礼,王作伟.非线性破坏准则下浅埋隧道围岩压力的极限分析[J].中南大学学报(自然科学版),2010,41(1):299-302.
[11]Hoek E,Brown E T.Practical estimates of rock mass strength[J].International Journal of Rock Mechanics and Mining Sciences,1997,34(8):1165-1186.
[12]Hoek E,Carranza-Torres C.Hoek-Brown failure criterion-2002Edition[C]∥Proceedings of the Fifth North American Rock Mechanics Symposium,2002:18-22.
[13]尹鑫,周海祚,郑刚.地震作用下临近边坡的条形基础极限承载力研究[J].岩土工程学报,2017,39(s2):95-98.
[2]王志凯,夏唐代,陈炜昀.刚性挡土墙地震主动土压力的拟动力学分析[J].浙江大学学报(工学版),2012,46(1):46-51.
[3]黄睿,夏唐代,钟丽娜,等.地震作用下挡土墙抗滑动稳定性的拟动力分析[J].中南大学学报(自然科学版),2014(9):3186-3192.
[4]Choudhury D,Nimbalkar S S.Pseudo-dynamic approach of seismic active earth pressure behind retaining wall[J].Geotechnical and Geological Engineering,2006,24(5):1103-1113.
[5]Choudhury D,Nimbalkar S.Seismic passive resistance by pseudo-dynamic method[J].Géotechnique,2005,55(9):699-702.
[6]罗根传,胡庆国,谭积青.基于极限平衡法与强度折减法的高边坡过程稳定性分析[J].矿冶工程,2013,33(2):14-17.
[7]刘秀军,贺建清.径向条分极限分析法在土坡稳定性分析中的应用[J].矿冶工程,2011,31(2):12-15.
[8]孙志彬,潘秋景,杨小礼,等.非均质边坡上限分析的离散机构及应用[J].岩石力学与工程学报,2017,36(7):1680-1688.
[9]杨小礼.岩石极限分析非线性理论及其应用[J].中南大学学报(自然科学版),2009,40(1):225-229.
[10]杨小礼,王作伟.非线性破坏准则下浅埋隧道围岩压力的极限分析[J].中南大学学报(自然科学版),2010,41(1):299-302.
[11]Hoek E,Brown E T.Practical estimates of rock mass strength[J].International Journal of Rock Mechanics and Mining Sciences,1997,34(8):1165-1186.
[12]Hoek E,Carranza-Torres C.Hoek-Brown failure criterion-2002Edition[C]∥Proceedings of the Fifth North American Rock Mechanics Symposium,2002:18-22.
[13]尹鑫,周海祚,郑刚.地震作用下临近边坡的条形基础极限承载力研究[J].岩土工程学报,2017,39(s2):95-98.
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