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波浪作用下黄河三角洲海底粉土液化特征对比研究

宋玉鹏 孙永福 宋丙辉 董立峰 杜星

宋玉鹏,孙永福,宋丙辉,等. 波浪作用下黄河三角洲海底粉土液化特征对比研究[J]. 海洋学报,2021,43(6):129–138 doi: 10.12284/hyxb2021100
引用本文: 宋玉鹏,孙永福,宋丙辉,等. 波浪作用下黄河三角洲海底粉土液化特征对比研究[J]. 海洋学报,2021,43(6):129–138 doi: 10.12284/hyxb2021100
Song Yupeng,Sun Yongfu,Song Binghui, et al. Comparative study on the liquefaction properties of seabed silt under wave loading in the Huanghe River Delta[J]. Haiyang Xuebao,2021, 43(6):129–138 doi: 10.12284/hyxb2021100
Citation: Song Yupeng,Sun Yongfu,Song Binghui, et al. Comparative study on the liquefaction properties of seabed silt under wave loading in the Huanghe River Delta[J]. Haiyang Xuebao,2021, 43(6):129–138 doi: 10.12284/hyxb2021100

波浪作用下黄河三角洲海底粉土液化特征对比研究

doi: 10.12284/hyxb2021100
基金项目: 国家自然科学基金青年基金(41806079,42007274);青岛海洋科学与技术试点国家实验室鳌山科技创新计划项目(2015ASKJ03)
详细信息
    作者简介:

    宋玉鹏(1979-),男,黑龙江省鸡西市人,研究员,博士,主要从事海洋工程地质方面工作。.E-mail:songyupeng@fio.org.cn

    通讯作者:

    孙永福(1964-),男,山东省潍坊市人,研究员,博士,主要从事海洋工程地质方面研究。E-mail:sunyongfu@fio.org.cn

  • 中图分类号: P714+.6

Comparative study on the liquefaction properties of seabed silt under wave loading in the Huanghe River Delta

  • 摘要: 作为一种常见的近海海底灾害地质现象,波致海床液化严重威胁着黄河三角洲地区海底工程设施的安全。粉质海床液化后,海底粉土的结构、物理和力学性质均发生了改变,研究该变化规律尤其是评估液化后海底粉土再次发生液化的可能性具有重要的理论意义和应用价值。本文利用室内动三轴仪对取自黄河三角洲已液化和未液化海底粉土开展了液化试验对比研究,讨论了已液化和未液化海底粉土在孔压增长模式和轴向动应变发展趋势方面的异同,对比分析了二者的液化势。研究结果表明:应变标准比孔压标准更适用于评估黄河三角洲地区海底粉土的液化势;孔压和动应变发展模式均表明与未液化粉土相比,已液化海底粉土再次发生液化的抗力有所提高;已液化和未液化海底粉土归一化孔压比ud/σ3与循环加载次数比N/Nf间相关关系可采用双曲线或指数函数模型进行定量化描述;未液化海底粉土的波致液化临界循环应力比约为0.20,已液化海底粉土的临界循环应力比约为0.35。研究成果有助于加深对海底粉土波致液化特性的认识,亦可为循环应力历史影响下的土体力学性质研究提供参考。
  • 图  1  研究区位置

    Fig.  1  Location of the study area

    图  2  液化扰动粉土层浅地层剖面影像

    Fig.  2  Sub-bottom profile of the liquefied silt stratum

    图  3  未液化扰动粉土层浅地层剖面影像

    Fig.  3  Sub-bottom profile of the non-liquefied silt stratum

    图  4  海底粉土颗分曲线

    Fig.  4  Distribution curves of particle size of seabed silt

    图  5  海底粉土孔压增长曲线

    Fig.  5  Pore pressure developing patterns of seabed silt

    图  6  液化前后海底粉土归一化孔压增长曲线对比

    Fig.  6  Comparison in the normalized pore pressure development between liquefied and non-liquefied seabed silt

    图  7  孔压发展双曲线模型和指数模型拟合结果

    Fig.  7  Fitting results of hyperbolic and exponential models for pore pressure development

    图  8  海底粉土轴向动应变发展曲线

    Fig.  8  Curves of axial dynamic strain with cycles for seabed silt

    图  9  液化前后海底粉土轴向动应变发展模式对比

    Fig.  9  Comparison in the axial strain developing patterns between liquefied and non-liquefied seabed silt

    图  10  循环应力比CSR与循环加载破坏次数Nf之间相关关系

    Fig.  10  Correlations between cyclic stress ratio and cycles at failure for seabed silt

    表  1  海底粉土基本物理性质指标

    Tab.  1  Physical properties of seabed silt

    分类海床以下深度/m含水量/%干密度/(g·cm−3比重孔隙比塑限/%液限/%塑性指数
    未液化粉土0.523.31.622.710.7018.726.88.1
    1.023.41.622.700.6919.127.07.9
    1.523.01.632.710.6917.626.89.2
    2.526.71.582.700.7121.328.57.2
    3.025.91.592.710.7121.930.58.6
    3.525.31.602.700.6921.729.98.2
    4.327.91.572.700.7222.631.69.0
    4.725.61.592.700.6921.629.78.1
    已液化粉土0.524.51.612.700.7020.627.67.0
    1.024.21.612.700.7020.626.35.7
    1.524.91.612.700.6918.626.17.5
    2.523.41.622.700.6620.628.17.5
    3.023.91.622.700.6720.627.97.3
    3.523.61.622.710.6719.727.78.0
    4.321.91.642.700.6415.925.29.3
    4.722.11.642.710.6516.724.57.8
    下载: 导出CSV

    表  2  循环应力加载方案

    Tab.  2  Cyclic dynamic stress loading program

    分类钻孔编号海床以下深度/m固结围压/kPa循环应力比初始模拟波浪状态
    波高/m波长/m水深/m
    未液化粉土ZK10.75~1.60200.35, 0.40, 0.506.060.010.0
    2.55~3.60300.23, 0.33, 0.37, 0.42, 0.474.760.010.0
    3.75~4.70400.23, 0.25, 0.30, 0.44, 0.485.260.010.0
    已液化粉土ZK30.95~1.85200.37, 0.45, 0.506.460.010.0
    2.48~3.50300.37, 0.42, 0.507.560.010.0
    3.70~4.70400.43, 0.45, 0.509.060.010.0
    下载: 导出CSV

    表  3  孔压发展双曲线模型拟合参数

    Tab.  3  Coefficients of hyperbolic model for pore pressure development

    分类围压/kPa模型CSR参数a参数b相关系数R2
    未液化粉土20双曲线0.350.5120.9180.99
    0.400.8180.7610.99
    0.500.3751.4940.98
    30双曲线0.230.0411.0250.99
    0.330.0420.9710.99
    0.370.2970.8900.99
    0.420.9510.8450.99
    0.470.6620.5670.99
    40双曲线0.230.1330.9730.99
    0.250.1540.9550.99
    0.300.3941.1490.99
    0.440.2750.8900.99
    0.480.3651.0900.99
    已液化粉土20双曲线0.370.1460.9060.99
    0.450.1281.0720.99
    0.500.0220.9690.99
    30双曲线0.370.4101.0720.98
    0.420.2771.1480.99
    0.500.5190.7120.99
    40双曲线0.430.5770.4270.99
    0.450.2920.9130.99
    0.500.4100.9520.98
    下载: 导出CSV
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出版历程
  • 收稿日期:  2020-06-18
  • 修回日期:  2020-10-19
  • 网络出版日期:  2021-04-02
  • 刊出日期:  2021-06-30

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