隧道洞口段结构地震响应分析
|
摘要
隧道的进出口大多是风化的松散堆积体,是抗震设防的薄弱环节。运用Newmark隐式时间积分有限元法,采用粘-弹性人工边界,对在地震荷载作用下围岩材料的渐变对隧道洞口段抗震性能进行分析。得到了3种工况下沿隧道轴线方向衬砌最大应力、位移以及加速度变化曲线,及不同工况下洞口段隧道结构的抗震设防长度。洞口段设防长度与洞口段围岩性质有关,洞口段围岩由软弱向坚硬渐变长度越长,洞口段衬砌应力就越大,洞口段设防长度就越长。
The tunnel portal and outlet are the weak links for anti-seismic fortifying as they are weathered accumulation bodies.Based on Newmarks implicit integration FEM and under the earthquake load,the inffluence on seismic responses in tunnel portal and outlet because of the changed surrounding rock is analyzed by using visco-elastic artificial boundary.The maximum stress,displacement and accelaration curve of lining along the axis direction of the tunnel under different work conditions are obtained,and the anti-seismic fortified lengths of tunnel structures are determined under different work conditions,providing the basis for selection of the anti-seismic fortified lengths of other similar tunnels.
The tunnel portal and outlet are the weak links for anti-seismic fortifying as they are weathered accumulation bodies.Based on Newmarks implicit integration FEM and under the earthquake load,the inffluence on seismic responses in tunnel portal and outlet because of the changed surrounding rock is analyzed by using visco-elastic artificial boundary.The maximum stress,displacement and accelaration curve of lining along the axis direction of the tunnel under different work conditions are obtained,and the anti-seismic fortified lengths of tunnel structures are determined under different work conditions,providing the basis for selection of the anti-seismic fortified lengths of other similar tunnels.
引文
[1]潘昌实.隧道地震灾害综述[J].隧道及地下工程,1990,11(2):1-9.
[2]高峰,严松宏.隧道时程动力反应分析改进算法[J].岩石力学与工程学报,2003,22(7):1088-1092.
[3]高峰,关宝树.沉管隧道三维地震反应分析[J].兰州铁道学院学报,2003,22(1):39-43.
[4]高峰,李德武.隧道三维地震反应分析若干问题的研究[J].岩土工程学报,1998,20(4):48-53.
[5]潘昌实.隧道及地下结构物抗震问题的研究概述[J].世界隧道,1996,16(5):7-16.
[6]于泳波,万振江,刘健新.减震技术在公路桥梁中的应用及地震反应分析[J].长安大学学报(自然科学版),2004,24(2):58-60.
[7]SHARMA S,WILLIAN R J,雷谦荣.地震对地下洞室的破坏[J].地下空间,1992,12(4):335-344.
[8]许增会,宋宏伟.地震对隧道围岩稳定性影响的数值模拟分析[J].中国矿业大学学报,2004,33(1):41-44.
[9]蔡佳骏,李之达,易辉,等.ANSYS二维弹塑性分析在联拱隧道围岩稳定性评价中的应用[J].水利与建筑工程学报,2005,3(1):10-14.
[2]高峰,严松宏.隧道时程动力反应分析改进算法[J].岩石力学与工程学报,2003,22(7):1088-1092.
[3]高峰,关宝树.沉管隧道三维地震反应分析[J].兰州铁道学院学报,2003,22(1):39-43.
[4]高峰,李德武.隧道三维地震反应分析若干问题的研究[J].岩土工程学报,1998,20(4):48-53.
[5]潘昌实.隧道及地下结构物抗震问题的研究概述[J].世界隧道,1996,16(5):7-16.
[6]于泳波,万振江,刘健新.减震技术在公路桥梁中的应用及地震反应分析[J].长安大学学报(自然科学版),2004,24(2):58-60.
[7]SHARMA S,WILLIAN R J,雷谦荣.地震对地下洞室的破坏[J].地下空间,1992,12(4):335-344.
[8]许增会,宋宏伟.地震对隧道围岩稳定性影响的数值模拟分析[J].中国矿业大学学报,2004,33(1):41-44.
[9]蔡佳骏,李之达,易辉,等.ANSYS二维弹塑性分析在联拱隧道围岩稳定性评价中的应用[J].水利与建筑工程学报,2005,3(1):10-14.
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