Influence of soil-structure interface characteristics on seismic response of underground structure in the local liquefaction interlayer site
YAN Guanyu1,XU Chengshun1,ZHANG Zihong1,SONG Jia2,DOU Pengfei3
(1. Key Laboratory of Urban Security and Disaster Engineering,Ministry of Education,Beijing University of Technology,Beijing 100124,China;2. School of Civil Engineering,North China University of Technology,Beijing 100144,China;
3. Department of Hydraulic Engineering,Tsinghua University,Beijing 100084,China)
闫冠宇1,许成顺1,张梓鸿1,宋 佳2,豆鹏飞3. 局部液化夹层场地土–结接触特性对地下结构地震响应的影响研究[J]. 岩石力学与工程学报, 2023, 42(S1): 3643-3653.
YAN Guanyu1,XU Chengshun1,ZHANG Zihong1,SONG Jia2,DOU Pengfei3. Influence of soil-structure interface characteristics on seismic response of underground structure in the local liquefaction interlayer site. , 2023, 42(S1): 3643-3653.
[1] WOOD J H. Earthquake design of rectangular underground structures[J]. Bulletin of the New Zealand Society for Earthquake Engineering,2007,40(1):1–6.
[2] IIDA H,HIROTO T,YOSHIDA N,et al. Damage to Daikai subway station[J]. Soils and foundations,1996,36(Special):283–300.
[3] WANG W L,WANG T T,SU J J,et al. Assessment of damage in mountain tunnels due to the Taiwan Chi-Chi earthquake[J]. Tunnelling and Underground Space Technology,2001,16(3):133–150.
[4] WANG Z Z,GAO B,JIANG Y J,et al. Investigation and assessment on mountain tunnels and geotechnical damage after the Wenchuan earthquake[J]. Science in China Series E:Technological Sciences,2009,52(2):546–558.
[5] CHEN S,TANG B,ZHAO K,et al. Seismic response of irregular underground structures under adverse soil conditions using shaking table tests[J]. Tunnelling and Underground Space Technology,2020,95:103145.
[6] AN J,TAO L,JIANG L,et al. A shaking table-based experimental study of seismic response of shield-enlarge-dig type?s underground subway station in liquefiable ground[J]. Soil Dynamics and Earthquake Engineering,2021,147:106621.
[7] DING X,ZHANG Y,WU Q,et al. Shaking table tests on the seismic responses of underground structures in coral sand[J]. Tunnelling and Underground Space Technology,2021,109:103775.
[8] CHEN G,CHEN S,QI C,et al. Shaking table tests on a three-arch type subway station structure in a liquefiable soil[J]. Bulletin of Earthquake Engineering,2015,13(6):1 675–1 701.
[9] CHEN G,WANG Z,ZUO X,et al. Shaking table test on the seismic failure characteristics of a subway station structure on liquefiable ground[J]. Earthquake Engineering and Structural Dynamics,2013,42(10):1 489–1 507.
[10] 陈国兴,左 熹,王志华,等. 地铁车站结构近远场地震反应特性振动台试验[J]. 浙江大学学报:工学版,2010,44(10):1 955–1 961. (CHEN Guoxing,ZUO Xi,WANG Zhihua,et al. Shaking table model test of subway station structure under far field and near field ground motion[J]. Journal of Zhejiang University:Engineering Science,2010,44(10):1 955–1 961.(in Chinese))
[11] YUE F,LIU B,ZHU B,et al. Shaking table test and numerical simulation on seismic performance of prefabricated corrugated steel utility tunnels on liquefiable ground[J]. Soil Dynamics and Earthquake Engineering,2021,141:106527.
[12] 刘春晓,陶连金,边 金,等. 可液化土层对地下结构地震反应的影响研究[J]. 铁道标准设计,2018,62(2):133–139.(LIU Chunxiao,TAO Lianjin,BIAN Jin,et al. Research on influence of liquefiable soil on seismic response of underground structure[J]. Railway Standard Design,2018,62(2):133–139.(in Chinese))
[13] CHEN R,YAO Y,WANG R,et al. Three-dimensional finite element analysis of underground structures? dynamic response in liquefiable soil[C]// Advances in Soil Dynamics and Foundation Engineering. Shanghai:[s. n.],2014:572–578.
[14] CHEN R,TAIEBAT M,WANG R,et al. Effects of layered liquefiable deposits on the seismic response of an underground structure[J]. Soil Dynamics and Earthquake Engineering,2018,113:124–135.
[15] CHEN R,WANG R,ZHANG J M. Dynamic response of underground structure under bidirectional shaking in layered liquefiable ground[C]// Proceedings of China-Europe Conference on Geotechnical Engineering. [S. l.]:Springer,Cham,2018:1 132–1 135.
[16] CHEN R R,WANG R,ZHANG J M,et al. Seismic response of a buried box structure in layered liquefiable grounds[C]// Earthquake Geotechnical Engineering for Protection and Development of Environment and Constructions. [S. l.]:CRC Press,2019:1 739– 1 745.
[17] 张孝波,景立平,孙海峰,等. 土–结构接触面对圆形隧道动力反应的影响[J]. 世界地震工程,2010,26(增1):326–329.(ZHANG xiaobo,JING liping,SUN haifeng,et al. Effect of soil-structure interface on dynamic response of circular tunnel[J]. World Earthquake Engineering,2010,26(Supp.1):326–329.(in Chinese))
[18] 杜修力,赵 源,李立云. 土体–结构界面接触对地下结构动力反应的影响[J]. 防灾减灾工程学报,2010,30(5):471–478.(DU Xiuli,ZHAO Yuan,LI Liyun. Contact effect of interfaces between soil and structure on dynamic response of underground structures[J]. Journal of Disaster Prevention and Mitigation Engineering,2010,30(5):471–478.(in Chinese))
[19] 庄海洋,吴 滨,陈国兴. 土–大型地铁地下车站结构动力接触效应研究[J]. 防灾减灾工程学报,2014,34(6):678–686.(ZHUANG Haiyang,WU Bin,CHEN Guoxing. Study on dynamic contact properties of soil-subway underground structure interaction system[J]. Journal of Disaster Prevention and Mitigation Engineering,2014,34(6):678–686.(in Chinese))
[20] 路德春,王 欣,罗 磊,等. 土与结构接触特性对地下结构地震反应的影响研究[J]. 防灾减灾工程学报,2017,37(2):177–186.(LU Dechun,WANG Xin,LUO Lei,et al. Research on the seismic responses of underground structures considering the soil and structure contact[J]. Journal of Disaster Prevention and Mitigation Engineering,2017,37(2):177–186.(in Chinese))
[21] 许紫刚. 地铁地下结构横断面抗震分析方法研究及减震技术初探[博士学位论文][D]. 北京:北京工业大学,2019.(XU Zigang. Research on seismic analysis methods and preliminary study on seismic control technologies of subway underground structures in transverse cross section [Ph. D. Thesis][D]. Beijing:Beijing University of Technology,2019.(in Chinese))
[22] LIU H,LIU H,ZHANG Y,et al. Coupling effects of surface building and earthquake loading on in-service shield tunnels[J]. Transportation Geotechnics,2021,26:100453.
[23] XU C,ZHANG Z,LI Y,et al. Validation of a numerical model based on dynamic centrifuge tests and studies on the earthquake damage mechanism of underground frame structures[J]. Tunnelling and Underground Space Technology,2020,104:103538.