自重、渗流及地震耦合作用下人工岛动力稳定性分析

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振动与冲击 ›› 2016, Vol. 35 ›› Issue (5) : 175-180.

论文

赖杰1,3 郑颖人1,2 李秀地1

作者信息 +

Dynamic stability analysis on an artificial island triggered by self weight, seepage and earthquake#br#

LAI Jie1, ZHENG Yingren1,2, LI Xiudi1

Author information +

文章历史 +

摘要

针对人工岛在自重、渗流、地震等耦合作用下动力稳定性研究较少的现状，以某人工岛边坡为例，首次将强度折减动力分析法引入到人工岛动力稳定性分析中，建立有限元数值分析模型，采用Finn-Byrne和修正Hardin-Drnevich动力本构，对多场耦合作用下人工岛液化范围、受力情况及动力稳定性进行分析。计算表明：1）在设防烈度地震作用下，人工岛能够满足动力稳定性要求，由于海底淤泥层抗剪强度很低，地震下的最终破裂面由抛填块石下部与淤泥层共同组成；2）岛内侧降水，使得海水渗流方向由岛外指向岛内，增加岛外侧土体有效应力，提高其抗液化能力，降低了岛内土体的有效应力，因此地震作用下内侧土体更易液化；3）由于受到周围土体的约束作用，土体局部液化不会产生液化大变形，只有液化土体较多才会产生大变形。研究结果为人工岛动力分析提供参考。

Abstract

Because there was little research on artificial island under the action of gravity, seepage, earthquake and other coupling forces, strength reduction dynamic analysis method was introduced to the dynamic stability on an artificial island. Establish finite element numerical model and use dynamic constitutive equations of Finn-Byrne as well as modified Hardin-Drnevich for this artificial island under earthquake. Analyze the scope of liquefaction, stress distribution, and dynamic stability. Calculation results show that: 1) this island can meet the requirement of dynamic stability. Because shear strength of muck layer is quite low, the final fracture surface is composed by the lower part of stone and mud layer under earthquake; 2) owing to precipitation, water seepage flow from outside to inside of the island, effective stress and liquefaction resistance of soil increase from the outside of the island, however, the ones from inside of the island get lower. So the soil from outside is more likely to be liquefied; 3) due to the constraints of surrounding soils, soil liquefaction won't lead to high deformation, only more liquefied soil can do. The results provide reference for dynamic analysis of the artificial island.

导出引用

赖杰1,3 郑颖人1,2 李秀地1. 自重、渗流及地震耦合作用下人工岛动力稳定性分析[J]. 振动与冲击, 2016, 35(5): 175-180

LAI Jie1, ZHENG Yingren1,2, LI Xiudi1. Dynamic stability analysis on an artificial island triggered by self weight, seepage and earthquake#br#[J]. Journal of Vibration and Shock, 2016, 35(5): 175-180

参考文献

[1] 王彦林，吴泽生. 港珠澳大桥东、西人工岛施工图设计安全风险评估[J]. 施工技术,2013,42(11):64-68.
Wang Yanlin，Wu Zesheng. Risk Assessment for the Construction Drawing Design of the East and West Artificial Islands of Hong Kong-Zhuhai-Macao Bridge [J]. CONSTRUCTION TECHNOLOGY, 2013,42(11):64-68.
[2] LIAN, W. D., FINN. 海浪和地震荷载下人工岛的性能-现场数据分析[J]. 海岸工程,1994,13(2):111-117.
[3] 刘海笑，王仲捷. 结构-波浪-海床藕合系统中大圆筒结构的波压力响应[J].水利学报,2003(4):67-74.
LIU Hai-xiao, WANG Zhong-jie. Wave pressure response of large cylindrical structures in seabed-wave-structure coupling system[J].JOURNAL OF HYDRAULIC ENGINEERING, 2003(4):67-74.
[4] 肖忠. 软土地基上新型防波堤结构的稳定性分析(博士学位论文)[D].天津，天津大学，2009.
Xiao Zhong. Stability analysis for new types of breakwaters on soft foundation[D].Tianjin, Tianjin University, 2009.
[5] 房卓. 梳式防波堤的水动力学特性研究(博士学位论文)[D].辽宁：大连理工大学，2011.
Fang Zhuo. Research on hydro dynamic Performance of comb-type breakwater [D].Liaoning, Dalian University of Technology,2011.
[6] 王公伯，李广雪，徐继尚. 近海人工岛稳定评价方法体系的研究[J].海洋地质与第四纪地质,2011,31(4):83-88.
Wang Gongbo, Li Guangxue, Xu Jishang. A STABILITY EVALUATION SYSTEM FOR OFFSHORE ARTIFICIAL ISLANDS[J].MARINE GEOLOGY & QUATRN- ARY GEOLOGY, 2011,31(4):83-88.
[7] 丁勇春，李光辉，王建华. 海上人工岛内深基坑变形与稳定分析[J].岩土工程学报,2012,34(supp.):519-524.
DING Yong-chun, LI Guang-hui, WANG Jian-hua. Deformation and stability of deep excavations in artificial offshore island[J]. Chinese Journal of Geotechnical Engineering, 2012,34(supp.):519-524.
[8] 丁勇春，李光辉，王建华. 海上人工岛内深基坑变形与稳定分析[J]. 岩土工程学报, 2012,34(增刊)：519-524.
DING Yong-chun, LI Guang-hui, WANG Jian-hua. Deformation and stability of deep excavations in artificial offshore island[J]. Chinese Journal of Geotechnical Engineering, 2012,34(supp.)：519-524.
[9] 郑颖人，叶海林，黄润秋等. 边坡地震稳定性分析探讨[J].地震工程与工程振动,2010,30(2):173-180.
ZHENG Yingren, YE Hailin, HUANG Runqiu, et al. Study on the seismic stability analysis of a slope[J]. JOURNAL OF EARTHQUAKE ENGINEERING AND ENGINEERING VIBRATION, 2010,30(2):173-180.
[10] 郑颖人，赵尚毅. 岩土工程极限分析有限元法及其应用[J]. 土木工程学报,2005,38(1):91-98.
Zheng Yingren, Zhao Shangyi. LIMIT STATE FINITE ELEMENT METHOD FOR GEOTECHNICAL ENGINEERING ANALYSIS AND ITS APPLICATIONS[J]. CHINA CIVIL ENGINEERING JOURNAL, 2005, 38(1):91-98.
[11] BIOT M A. General Solution of the Equation of Elasticity and Consolidation for a Porous Material [J]Journal of Applied Mechanics, 1956, 23: 91-96.
[12] Itasca Consulting Group Inc. Fast Lagrangian Analysis of Continua in 3 Dimensions [M]. Minneapolis: Itasca Consulting Group Inc 2002.
[13] Martin, G. R., W. D. L. Finn and H. B. Seed. Fundamentals of Liquefaction Under Cyclic Loading [J]. Geotech., Div. ASCE, 1975,101(GT5), 423-438.
[14] Byrne, P. A Cyclic Shear-Volume Coupling and Pore-Pressure Model for Sand [J]. Geotechnical Earthquake Engineering and Soil Dynamics, 1991, 24(1), 47-55.
[15] Hardin, B. O., and Drnevich, V. P. “Shear Modulus and Damping in Soils: I. Measurement and Parameter Effects, II. Design Equations and Curves,” Technical Reports UKY 27-70-CE 2 and 3, College of Engineering, University of Kentucky, Lexington, Kentucky.
[16] 庄海洋.土-地下结构非线性动力相互作用及其大型振动台试验研究(博士学位论文)[D].南京：南京工业大学，2006.
Zhuang Haiyang. Study on Nonlinear Dynamic Soil-Underground Structure Interaction and Its Large Size Shaking Table Test.[D].Nanjing: Nanjing University of Technology, 2006.