近断层地震下可液化场地土反应的数值模拟
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摘要
液化条件下场地土大变形是造成工程结构失效的主要原因之一。文中以某高速公路特大桥的可液化岸坡近场场地为研究对象,基于PL-Finn液化本构模型,利用FLAC 3D程序对其在地震作用下的动响应全过程进行了数值模拟分析。结果表明,PL-Finn模型可较好地反映地震过程中孔隙水压、液化区的变化规律,并能较好的预测液化后场地土的变形规律。液化引起的地基土大变形对桥梁桩基的影响需引起重视。
The large displacement of sandy soils due to seismic liquefaction is one of the main sources that induce the failure of engineering structures.The sloping site for a highway bridge at near-fault region is presented in this paper,and based on PL-Finn constitutive model,the process of the seismic response due to liquefaction is simulated by using FLAC 3D.The numerical simulations indicate that the PL-Finn model can better demonstrate the variation of the pore water pressure,the liquefied zone distribution and the large displacement of the liquefied site soils.Much attention needs to be paid for the effect of the large displacement of site soils due to the seismic liquefaction on the bridge pile foundations.
The large displacement of sandy soils due to seismic liquefaction is one of the main sources that induce the failure of engineering structures.The sloping site for a highway bridge at near-fault region is presented in this paper,and based on PL-Finn constitutive model,the process of the seismic response due to liquefaction is simulated by using FLAC 3D.The numerical simulations indicate that the PL-Finn model can better demonstrate the variation of the pore water pressure,the liquefied zone distribution and the large displacement of the liquefied site soils.Much attention needs to be paid for the effect of the large displacement of site soils due to the seismic liquefaction on the bridge pile foundations.
引文
[1]高玉峰,刘汉龙,朱伟.地震液化引起的地面大位移研究进展[J].岩土力学,2000,21(3):294-298.
[2]陈国兴,胡庆兴,刘雪珠.关于砂土液化判别的若干意见[J].地震工程与工程振动,2002,22(1):141-151.
[3]Zhang Guangwen.Estimation of liquefaction induced ground deformations by CPT&SPT-based approaches[D].Canada:University of Alberta,2001.
[4]张建民,王刚.砂土液化大变形的机理[J].岩土工程学报,2006(7):835-840.
[5]周云东,刘汉龙,高玉峰,等.砂土地震液化后大位移室内试验研究探讨[J].地震工程与工程振动,2002,22(1):152-156.
[6]FLAC 3D,Fast lagrangian analysis of continua in 3 dimensions[M].USA:ITASCA Consulting Group,2003.
[7]秦建设.盾构施工开挖面变形与破坏机理研究[D].南京:河海大学,2005.
[8]陈育民.砂土液化后流动大变形试验与计算方法研究[D].南京:河海大学,2007.
[2]陈国兴,胡庆兴,刘雪珠.关于砂土液化判别的若干意见[J].地震工程与工程振动,2002,22(1):141-151.
[3]Zhang Guangwen.Estimation of liquefaction induced ground deformations by CPT&SPT-based approaches[D].Canada:University of Alberta,2001.
[4]张建民,王刚.砂土液化大变形的机理[J].岩土工程学报,2006(7):835-840.
[5]周云东,刘汉龙,高玉峰,等.砂土地震液化后大位移室内试验研究探讨[J].地震工程与工程振动,2002,22(1):152-156.
[6]FLAC 3D,Fast lagrangian analysis of continua in 3 dimensions[M].USA:ITASCA Consulting Group,2003.
[7]秦建设.盾构施工开挖面变形与破坏机理研究[D].南京:河海大学,2005.
[8]陈育民.砂土液化后流动大变形试验与计算方法研究[D].南京:河海大学,2007.
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