海洋土地基核电厂盾构排水隧洞地震响应研究
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摘要
以某核电站的取排水工程为例,将典型核电地震波RG1.60谱人工波作为地震荷载,采用等价线性法对海洋土地基地下隧洞进行了平面有限元地震响应分析,通过计算总结了穿越不同的海洋土土质条件、不同埋深、管片接缝刚度、管片厚度及竖向地震对隧洞的衬砌受力与变形的影响,获得了此类盾构隧洞的动力响应特性规律,为隧洞抗震分析提供了参考依据。
Taking water intake and drainage project of nuclear power plant for an example,equivalent linear method is applied to analyze two-dimensional finite element seismic response of underground tunnel with ocean soil foundation by taking the typical nuclear power seismic wave RG1.60 as seismic load.The relationship between lining force of tunnel and deformation is analyzed under different soil conditions,different embedded depth,joints stiffness of duct piece,lining thickness and vertical earthquake.Dynamic response characteristics of shield tunnel is obtained,which provides reference for aseismic analysis of tunnel.
Taking water intake and drainage project of nuclear power plant for an example,equivalent linear method is applied to analyze two-dimensional finite element seismic response of underground tunnel with ocean soil foundation by taking the typical nuclear power seismic wave RG1.60 as seismic load.The relationship between lining force of tunnel and deformation is analyzed under different soil conditions,different embedded depth,joints stiffness of duct piece,lining thickness and vertical earthquake.Dynamic response characteristics of shield tunnel is obtained,which provides reference for aseismic analysis of tunnel.
引文
[1]国家地震局工程力学研究所,核工业第二研究设计院,上海核工程研究设计院,等.核电厂抗震设计规范(GB50267-1997)[S].北京:中国计划出版社,1997.
[2]潘昌实.隧道地震灾害综述[J].隧道及地下工程,1990,11(2):1-9.
[3]赵杰,王桂萱,裴强,等.核电厂取水隧洞抗震分析[J].世界地震工程,2009,25(3):135-139.
[4]刘德付,苏华友.不同地层中隧洞管片衬砌结构计算分析[J].地下空间与工程学报,2009,5(2):262-265.
[5]Rober Rowe,Meng(Hons)ARSM.地震带的隧道开挖[J].雷谦荣译.地下空间,1994(2):138-144.
[6]黄钟晖,廖少明,刘国彬.管片厚度对隧道受力及使用性能的影响[J].建筑技术,2000,31(7):471-472.
[7]国胜兵,赵毅,赵跃堂,等.地下结构在竖向和水平地震荷载作用下的动力分析[J].地下空间,2002,22(4):314-319.
[8]中国建筑科学研究院,中国地震局工程力学研究所,中国建筑技术研究院,等.建筑抗震设计规范(GB50011-2010)[S].北京:中国建筑工业出版社,2010.
[9]日本土木学会.隧道标准规范(盾构篇)及解说[M].朱伟译.北京:中国建筑工业出版社,2001.
[10]董哲仁.日本盾构施工技术新进展[J].水利水电技术,2001,32(9):29-32.
[11]John C M St,Zahrah T F.Aseismic Design of Un-derground Structure[J].Tunnelling and Under-ground Space Technology,1987,2(2):165-197.
[12]Hashash Y M A,Hook J J,Schmidt B,et a1.Seis-mic Design and Analysis of Underground Structures[J].Tunnelling and Underground Space Technolo-gy,2001,16(4):247-293.
[2]潘昌实.隧道地震灾害综述[J].隧道及地下工程,1990,11(2):1-9.
[3]赵杰,王桂萱,裴强,等.核电厂取水隧洞抗震分析[J].世界地震工程,2009,25(3):135-139.
[4]刘德付,苏华友.不同地层中隧洞管片衬砌结构计算分析[J].地下空间与工程学报,2009,5(2):262-265.
[5]Rober Rowe,Meng(Hons)ARSM.地震带的隧道开挖[J].雷谦荣译.地下空间,1994(2):138-144.
[6]黄钟晖,廖少明,刘国彬.管片厚度对隧道受力及使用性能的影响[J].建筑技术,2000,31(7):471-472.
[7]国胜兵,赵毅,赵跃堂,等.地下结构在竖向和水平地震荷载作用下的动力分析[J].地下空间,2002,22(4):314-319.
[8]中国建筑科学研究院,中国地震局工程力学研究所,中国建筑技术研究院,等.建筑抗震设计规范(GB50011-2010)[S].北京:中国建筑工业出版社,2010.
[9]日本土木学会.隧道标准规范(盾构篇)及解说[M].朱伟译.北京:中国建筑工业出版社,2001.
[10]董哲仁.日本盾构施工技术新进展[J].水利水电技术,2001,32(9):29-32.
[11]John C M St,Zahrah T F.Aseismic Design of Un-derground Structure[J].Tunnelling and Under-ground Space Technology,1987,2(2):165-197.
[12]Hashash Y M A,Hook J J,Schmidt B,et a1.Seis-mic Design and Analysis of Underground Structures[J].Tunnelling and Underground Space Technolo-gy,2001,16(4):247-293.
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