排架式微型桩组合结构受力分析
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摘要
排架式微型桩组合结构作为边坡防护的一种轻型支挡结构,施工安全便捷,对非常环境适应性强。基于弹性地基梁理论应用的基本条件是土体为稳定体,以及排架式微型桩组合结构对不稳定坡体的改善作用使不同位置的微型桩前抗力条件有所差别,在弹性地基梁理论的基础上,借鉴一般微型桩水平承载力计算的思路,通过不同的m(弹性抗力系数)计算值和桩顶大变形对m值的限定条件,来体现微型桩前其他微型桩的存在对地基反力的贡献。以3种基本计算模型建立排架式微型桩组合结构的计算公式,计算并分析该类桩群的内力及对地震力的特殊反应,为微型桩的设计提供一定的参考依据。
The composite structure of row posture micro-piles,as a light-weight protection structure in side-slope protection,has the advantages of safe and quick construction and high adaptability to some special environments.A basic requirement of the elastic foundation-beam theory application is that the foundation should be stable.Because the row posture micro-piles composite structure improves the stability of slope,the resistant forces in front of different positions of micro-piles are different.On the basis of the elastic foundation-beam theory and by using the idea of the general micro-piles horizontal bearing capacity calculation method,the row posture micro-piles advantages are revealed by the different calculated m(the coefficient of rock resistance) values and the limited conditions of pile top large deformation.The computational formula of row posture micro-pile composite structure is established from three basic calculation models.The special response to seismic force is calculated and analyzed in a practical case,which may provide certain reference for the micro-piles design.
The composite structure of row posture micro-piles,as a light-weight protection structure in side-slope protection,has the advantages of safe and quick construction and high adaptability to some special environments.A basic requirement of the elastic foundation-beam theory application is that the foundation should be stable.Because the row posture micro-piles composite structure improves the stability of slope,the resistant forces in front of different positions of micro-piles are different.On the basis of the elastic foundation-beam theory and by using the idea of the general micro-piles horizontal bearing capacity calculation method,the row posture micro-piles advantages are revealed by the different calculated m(the coefficient of rock resistance) values and the limited conditions of pile top large deformation.The computational formula of row posture micro-pile composite structure is established from three basic calculation models.The special response to seismic force is calculated and analyzed in a practical case,which may provide certain reference for the micro-piles design.
引文
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[2]Shields D R.Buckling of micro-piles[J].Journal ofGeotechnical and Geoenvironmental Engineering,ASCE,2007,133(3):334-337.
[3]Cadden A,Gomez J,Bruce D,et al.Micro-piles:recentadvances and future trends[C]∥Current Practices andFuture Trends in Deep Foundations.Reston,USA:American Society of Civil Engineers,2004:140-165.
[4]丁光文.微型桩处理滑坡的设计方法[J].西部探矿工程,2001,13(4):15-17.
[5]史佩栋,何开胜.小桩的起源、应用与发展(Ⅱ)[J].岩土工程界,2005,8(9):15-18.
[6]冯君,周德培,江南,等.微型桩体系加固顺层岩质边坡的内力计算模式[J].岩石力学与工程学报,2006,25(2):284-288.
[7]肖世国,鲜飞,王唤龙.一种微型桩组合抗滑结构内力分析方法[J].岩土力学,2010,31(8):2553-2559.
[8]周德培,王唤龙,孙宏伟.微型桩组合抗滑结构及其设计理论[J].岩石力学与工程学报,2009,28(7):1353-1362.
[9]韩金平.液化场地微型桩基地震响应数值仿真研究[D].合肥:合肥工业大学,2007.
[10]贺传友.液化场地微型桩基地震响应三维数值分析[D].合肥:合肥工业大学,2009.
[11]陈正,梅岭,梅国雄.柔性微型桩水平承载力数值模拟[J].岩土力学,2011,32(7):2219-2224.
[12]罗红明,唐辉明,胡斌,等.考虑地震力的刚体极限平衡法及其工程应用[J].岩石力学与工程学报,2007,26(1):3590-3595.
[13]王念秦,姚勇,罗东海.滑坡综合治理方案比选评价模型[J].水土保持通报,2009,29(1):111-114.
[14]严金凯,殷跃平,门玉明,等.滑坡微型桩群加固工程试验研究[J].土木工程学报,2011,44(4):120-128.
[15]贾庆山.桩基水平承载力标准值与m值确定[J].特种结构,1995,12(2):23-24.
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