饱和砂土地基液化处置方案效果评价至关重要,关系到液化处置方案的有效性和经济性,可以实现设计方案最优化。孟加拉吉大港盾构隧道存在地基地震液化问题,须采取有效的液化处置措施才能确保工程的安全性。本文从机理上分析了碎石桩液化处置的优势,提出了合理的液化处置方案。而且在定性分析的基础上,对该项目的地基碎石桩液化处置效果进行数值分析与评价:利用有限差分程序FLAC3D,分别建立碎石桩加固前和加固后的三维动力计算模型,通过计算分析液化处置前后的超孔压比、超静孔隙水压力、抗浮特性等,定量评价液化处置效果。研究表明该碎石桩液化处置方案效果明显,各方面抗震特性均有效提升。
Abstract
The evaluation of the effect of the liquefaction disposal scheme of saturated sand foundation is very important. It is related to the effectiveness and economy of the liquefaction disposal scheme, and the design scheme can be optimized. There is a ground liquefaction problem in the shield tunnel of Chittagong, Bangladesh. Effective liquefaction measures must be taken to ensure the safety of the project. This paper analyzes the advantages of liquefaction disposal of gravel piles from the mechanism and proposes a reasonable liquefaction disposal plan. On the basis of qualitative analysis, the numerical analysis and evaluation of the liquefaction effect of the base gravel pile is carried out. Using the finite difference program FLAC3D, the three-dimensional dynamic calculation model of the gravel pile before and after reinforcement is established. The liquefaction disposal effect was quantitatively evaluated by the excess pore pressure ratio, the excess pore water pressure, and the anti-floating property before and after the liquefaction treatment. The research shows that the liquefaction disposal scheme of the gravel pile has obvious effects, and the seismic characteristics of all aspects are effectively improved.
关键词
碎石桩 /
液化处置 /
效果评价 /
FLAC 3D
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Key words
gravel pile /
liquefaction disposal /
effect evaluation /
FLAC 3D
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参考文献
[1]王刚, 张建民.地震液化问题研究进展[J].力学进展, 2007, 37(4):575-589
[2]刘汉龙, 赵明华.地基处理研究进展[J].土木工程学报, 2016, 49(1):96-115
[3]张辉杰, 胡先举, 李学海, 等.三峡二期围堰风化砂砾振冲加固检测成果分析[J].长江科学院院报, 2002, 19(4):30-32
[4] 蒋关鲁, 赵如意, 刘先峰.京沪高速铁路饱和粉土地基碎石桩加固前后液化特性研究[C]// 全国防震减灾工程学术研讨会. 2007.
[5] Seed H.B., Booker J.R. Stabilization of Potenially Liquefialle Sand Deposits Using Gravel Drains Systems[C]// Earthquake Engineering Research Center, University of California, Berkeley, California, 1976, 76-110.
[6]徐志英.用砾石排水桩抗地震液化的砂基孔压计算[J].地震工程与工程振动, 1992, 12(4):88-92
[7]刘松玉, 方磊, 胡雪辉.干振碎石桩加固液化地基试验研究[J].工程地质学报, 2000, 8(4):488-492
[8]高彦斌, 叶观宝, 徐超, 等.一种新的碎石桩法处理液化粉土地基的设计方法[J].土木工程学报, 2005, 38(5):77-81
[9] Baez J.I. A design model for the reduction of soil liquefaction by vibro-stone columns[D]. Los Angeles, CA: University of Southern California, 1995.
[10] 郑建国, 姚克俭, 郝增志.振动挤密碎石桩加固粉土地基试验研究[C]. 第三届地基处理学术讨论会论文集, 浙江: 浙江大学出版社, 1992, 367-374.
[11]潘永庆, 孙立强, 王吉超, 等.碎石桩加固液化粉土地基的数值模拟分析[J].地震工程学报, 2014, 36(3):540-543
[12]Sasaki Y.Taniguchi EShaking table tests on gravel drains to prevent liquefaction of sand deposits[J].Soil and Foundations, 1982, 22(3):1-14
[13]杨继红, 董金玉, 黄志全, 等.夯扩挤密碎石桩加固液化砂土地基的动力数值分析[J].岩土力学, 2014, 35(S2):593-599
[14] 张向东, 张晋, 苏伟林.基于PL-Finn模型的饱和砂土液化数值分析[J].辽宁工程技术大学学报自然科学版, 2017, 36(7):724-728
[15] 陈育民, 徐鼎平.FLAC/FLAC3D基础与工程实例[M]. 中国水利水电出版社, 2013.
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