扎囊大桥桥址地区砂土液化问题研究
|
摘要
以西藏扎囊大桥工程为例,在通过勘察、测试等手段掌握大量数据的基础上,对在建西藏山南地区雅鲁藏布江扎囊大桥桥址地区的砂土液化问题进行了研究。其结果表明:桥址区地基土的上、中部是饱和砂土层,其液化指数高达37.62~110.77,均远大于18,液化等级判定为严重;勘察探明,地基土下部为中密圆砾,承载力高,可作桥基基础持力层。
Taking the Zhanang Bridge Project in Tibet as an example,this paper,based on large amount of data obtained by way of survey and test,studied the sand liquefaction in the site of Zhanang Bridge on the Yarlung Zangbo River in the south mountainous area in Tibet. The result shows that the upper and middle part of the foundation soil in the site is saturated sand layer,with the liquefaction index up to 37. 62 ~ 110. 77 and far more than 18,thus the grade of liquefaction is judged as serious; and by surveys,the lower part of the foundation soil is proved to be medium-density cobble with high bearing capacity and may be used as the bearing layer for the bridge foundation.
Taking the Zhanang Bridge Project in Tibet as an example,this paper,based on large amount of data obtained by way of survey and test,studied the sand liquefaction in the site of Zhanang Bridge on the Yarlung Zangbo River in the south mountainous area in Tibet. The result shows that the upper and middle part of the foundation soil in the site is saturated sand layer,with the liquefaction index up to 37. 62 ~ 110. 77 and far more than 18,thus the grade of liquefaction is judged as serious; and by surveys,the lower part of the foundation soil is proved to be medium-density cobble with high bearing capacity and may be used as the bearing layer for the bridge foundation.
引文
[1]陈国兴.岩土地震工程学[M].北京:科学出版社,2007.
[2]凌贤长,郭明珠,王东升,等.液化场地桩基桥梁震害响应大型振动台模型试验研究[J].岩土力学,2006,27(1):7-10.
[3]龚士良,李采.上海长江隧桥工程环境地质问题与技术对策[J].水文地质工程地质,2008(3):81-86.
[4]徐鹏举,唐亮,凌贤长,等.可液化场地桩-土-桥梁结构地震相互作用简化计算方法研究[J].吉林大学学报,2010,40(5):1121-1127.
[5]徐鹏举.可液化场地桥梁桩基地震反应分析与简化分析方法研究[D].哈尔滨:哈尔滨工业大学,2011.
[6]刘林,杨庆山,张雪枫.沐河特大桥场地深层砂土液化势评价[J].土木建筑与环境工程,2010,32(增2):165-167.
[7]GB 18306-2001中国地震动参数区划图[S].北京:中国标准出版社,2001.
[8]GB 50011-2010建筑抗震设计规范[S].北京:中国建筑工业出版社,2010.
[9]JTGTB02-01-2008公路桥梁抗震设计细则[S].北京:人民交通出版社,2008.
[2]凌贤长,郭明珠,王东升,等.液化场地桩基桥梁震害响应大型振动台模型试验研究[J].岩土力学,2006,27(1):7-10.
[3]龚士良,李采.上海长江隧桥工程环境地质问题与技术对策[J].水文地质工程地质,2008(3):81-86.
[4]徐鹏举,唐亮,凌贤长,等.可液化场地桩-土-桥梁结构地震相互作用简化计算方法研究[J].吉林大学学报,2010,40(5):1121-1127.
[5]徐鹏举.可液化场地桥梁桩基地震反应分析与简化分析方法研究[D].哈尔滨:哈尔滨工业大学,2011.
[6]刘林,杨庆山,张雪枫.沐河特大桥场地深层砂土液化势评价[J].土木建筑与环境工程,2010,32(增2):165-167.
[7]GB 18306-2001中国地震动参数区划图[S].北京:中国标准出版社,2001.
[8]GB 50011-2010建筑抗震设计规范[S].北京:中国建筑工业出版社,2010.
[9]JTGTB02-01-2008公路桥梁抗震设计细则[S].北京:人民交通出版社,2008.
版权所有:© 2023 中国地质图书馆 中国地质调查局地学文献中心