渤海浅层沉积物剪切波速与深度的相关性分析
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摘要
剪切波速是工程场地地震安全性评价最重要的参数之一。本文应用大量渤海浅层沉积物的剪切波速实测数据,利用最小二乘法通过三种模型探讨了不同土质类型的剪切波速与深度的关系,给出了不同土质类型的剪切波速与深度拟合最佳的统计公式。并与《构筑物抗震设计规范》的推荐公式在某一海域工程场地的测试结果进行对比分析,结果表明:本文所建立的统计公式对剪切波速的预测效果明显好于规范所推荐的统计公式。因此本文所推荐的渤海不同土质类型的剪切波速与深度间的统计公式,可供无波速测试的渤海海洋工程场地借鉴使用。
The shear wave velocity of soils is one of the most important parameters in the field of geotechnical earthquake engineering.Based on the tested data of shear wave velocity of shallow sediments from lots of boreholes in Bohai Gulf,the best regression equations of shear wave velocity and depth for different types of soils are established by using three statistical models.The predicted shear wave velocity of soils with recommended equations are compared with the results of formula in the Chinese design code for earthquake resistance of special structures(GB50191-93) in a certain borehole.It is indicated that the fitting accuracy of recommended equations is better than that of formula in design code.Therefore,the recommended regression equations of shear wave velocity and depth of shallow sediments in Bohai Gulf can be used for marine sites of Bohai Gulf,whose shear wave velocities are not tested.
The shear wave velocity of soils is one of the most important parameters in the field of geotechnical earthquake engineering.Based on the tested data of shear wave velocity of shallow sediments from lots of boreholes in Bohai Gulf,the best regression equations of shear wave velocity and depth for different types of soils are established by using three statistical models.The predicted shear wave velocity of soils with recommended equations are compared with the results of formula in the Chinese design code for earthquake resistance of special structures(GB50191-93) in a certain borehole.It is indicated that the fitting accuracy of recommended equations is better than that of formula in design code.Therefore,the recommended regression equations of shear wave velocity and depth of shallow sediments in Bohai Gulf can be used for marine sites of Bohai Gulf,whose shear wave velocities are not tested.
引文
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[2]胡升瑞.波速测试在东营地区工程勘察中的应用[J].山西建筑,2006,32(2):124~125.
[3]王广军,苏经宇.连云港碱厂层状土剪切波速沿深度变化的推测[J].勘察科学技术,1986,(3):35~38.
[4]程祖锋,李萍,李燕等.深圳地区部分岩土类型剪切波速与深度的关系分析[J].工程地质学报,1997,5(2):163~168.
[5]陈国兴,徐建龙,袁灿勤.南京城区岩土体剪切波速与土层深度的关系[J].南京建筑工程学院学报,1998,45(2):32~37.
[6]高玉峰,刘汉龙.合肥膨胀土剪切波速的特征分析[J].岩土工程学报,2003,25(3):371~373.
[7]周锡元,王广军,苏经宇.场地.地基.设计地震[M].北京:地震出版社,1990.
[8]陶小三,杨伟林,高志兵等.南京河西地区岩土体剪切波速与深度的关系[J].防震减灾工程学报,2009,29(3):320~324.
[9]刘洪帅,郑桐,齐文浩等.常规土类剪切波速与埋深的关系分析[J].岩土工程学报,2010,32(7):1142~1149.
[10]王建华,程国勇.饱和砂土的剪切波速与抗液化强度相关性研究[J].岩土工程学报,2005,27(4):369~373.
[11]中华人民共和国国家标准.构筑物抗震设计规范(GB50191-93)[S].北京:中国建筑工业出版社,1993.
[12]袁钟.以剪切波速评价岩土工程特性[J].港工技术,2003,(4):48~51.
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