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| Engineering technology of framed anti-slide retaining structure crossing ancient landslide |
| CHEN Weizhi1,2,LI Anhong1,HU Huixing1,LIU Kaiwen2 |
| (1. China Railway Eryuan Engineering Group Co.,Ltd.,Chengdu,Sichuan 610031,China;2. School of Civil Engineering,
Southwest Jiaotong University,Chengdu,Sichuan 610031,China) |
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Abstract It becomes extremely easy to revitalize ancient landslides and increases the risks of engineering when excavation engineering crosses the ancient landslides. To meet the technical requirements for stability control of railway cuttings crossing huge ancient landslides,taking the framed anti-slide retaining structures(FARSs) as study object,the internal force calculation method of FARS was derived based on several calculation assumptions. Combined with the construction of an excavation engineering crossing the huge ancient landslide of Lindai—Zhijin railway,theoretical calculations,numerical simulation,construction method and filed test were carried out to reveal the internal force and displacement response characteristics of FARSs,the design method and construction technology of FARS were also proposed. The results:(1) The theoretical calculation results of the internal force of FARS were close to the results obtained from numerical simulation and filed test. The extreme values of bending moment and shear force were mainly located at the junction between piles and beams. These junctions were the key nodes for local strengthening of FARS. (2) It suggests that the front pile, the back pile and beam should be strengthened with the shear design when FARSs were applied to double–track railway,but secondary beam should be strengthened with the bending design. The internal forces of the front pile,back pile and beam were less affected by the operation speed,and the internal forces of the secondary beam increased slightly with the increase of operation speed. (3) The beams and secondary beams played a coordinated role in the deformation of front pile and back pile. The maximum lateral displacement of the front pile and back pile was less than 6.0mm under the landslide thrust,and FARS had good seismic performance in earthquake areas of nine degrees magnitudes and below(where the peak acceleration varying from 0.05 g to 0.4 g). (4) To build FARSs in an ancient landslide,the construction process should be from front to back,from top to bottom,alternate between piles,the construction technology should be sequential construction of front pile and back pile,partial cuts are reserved for connecting steel bars for beams,secondary beams and piles,back piles and beams are integrally poured. The results can be used a technical support to guide the subgrade construction and geological disaster prevention of Sichuan–Tibet railway,which is the representative railway in the complex and dangerous mountain areas.
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| [1] ARNAUD T,FAUSTO G,JALAL S,et al. The future of landslides'past-a framework for assessing consecutive landsliding systems[J]. Landslides,2020,17(7):1 519–1 528.
[2] 钟立勋. 意大利瓦伊昂水库滑坡的启示[J]. 中国地质灾害与防治学报,1993,5(2):77–84.(ZHONG Lixun. Enlightenment from vajont landslide in Italy[J]. The Chinese Journal of Geological Hazard and Control,1993,5(2):77–84.(in Chinese))
[3] PLAFKER G,ERICKSEN G E,CONCHA J F. Geological aspects of the May 31,1970,Peru earthquake[J]. Seismological Society of America Bulletin,1971,61(3):543–578.
[4] 谭继中. 云南头寨沟大型高速滑波运动特征探讨[J]. 地质灾害与环境保护,1993,4(1):37–44.(TAN Jizhong. Analysis of movement of huge high speed landslide in Touzhaigou,Yunnan Province[J]. Geological Hazards and Environment Preservation,1993,4(1):37–44.(in Chinese))
[5] 殷跃平. 斜倾厚层山体滑坡视向滑动机制研究–以重庆武隆鸡尾山滑坡为例[J]. 岩石力学与工程学报,2010,29(2):217–226.(YIN Yueping. Mechanism of apparent dip slide of inclined bedding rockslide—A case study of Jiweishan rockslide in Wulong,Chongqing[J]. Chinese Journal of Rock Mechanics and Engineering,2010,29(2):217–226.(in Chinese))
[6] 李安洪. 铁路滑坡防治技术总结[R]. 成都:中铁二院工程集团有限责任公司,2019.(LI Anhong. Summary of Railway Landslide Prevention Technology[R]. Chengdu:China Railway Eryuan Engineering Group Co.,Ltd,2019.(in Chinese))
[7] 中华人民共和国行业标准编写组. TB10027—2012铁路工程不良地质勘察规程[S]. 北京:中国铁道出版社,2012.(The Professional Standards Compilation Group of the People's Republic of China. TB10027—2012 Code for unfavorable geological condition investigation of railway engineering[S]. Beijing:China Railway Press,2012.(in Chinese))
[8] 胡余道. 铁西滑坡发生发展规律与整治工程实践[J]. 铁道标准设计,1987,(1):15–23.(HU Yudao. Law of occurrence and development of Tiexi landslide and practice of remediation project[J]. Railway Standard Design,1987,(1):15–23.(in Chinese))
[9] 薛翊国,孔凡猛,杨为民,等. 川藏铁路沿线主要不良地质条件与工程地质问题[J]. 岩石力学与工程学报,2020,39(3):1–24.(XUE Yiguo,KONG Fanmeng,YANG Weimin,et al. Main unfavorable geological conditions and engineering geological problems along Sichuan—Tibet railway[J]. Chinese Journal of Rock Mechanics and Engineering,2020,39(3):1–24.(in Chinese))
[10] 汪小平,孙云志. 中国西南地区重大工程中面临的工程地质问题与勘测技术需求[J]. 资源环境与工程,2008,(1):32–34.(WANG Xiaoping,SUN Yunzhi. Engineering geologic issues and exploration technology demands of large scale project in southwest area of China[J]. Resources Environment and Engineering,2008,(1):32–34.(in Chinese))
[11] 漆宝瑞. 南昆铁路[M]. 成都:电子科技大学出版社,2006:346–357.(QI Baorui. Nanning–Kunming railway[M]. Chengdu:University of Electronic Science and Technology of China Press,2006:346–357.(in Chinese))
[12] HASSIOTIS S,CHAMEAU J L,GUNARATNE M. Design method for stabilization of slopes with piles[J]. Journal of Geotechnical and Geoenvironmental Engineering,1997,125(10):314–323.
[13] 王贵华,李长冬,陈文强,等. 复合多层滑床条件下锚索抗滑桩受力特征研究[J]. 岩石力学与工程学报,2019,38(11):2 219–2 230.(WANG Guihua,LI Changdong,CHEN Wenqiang,et al. Mechanical characteristics of anchored slide–resistant piles under the condition of composite multilayer sliding bed[J]. Chinese Journal of Rock Mechanics and Engineering,2019,38(11):2 219–2 230.(in Chinese))
[14] 中华人民共和国行业标准编写组. TB10025—2019 铁路路基支挡结构设计规范[S]. 北京:中国铁道出版社,2019.(The Professional Standards Compilation Group of People's Republic of China. TB10025—2019 Code for design on retaining structures of railway subgrade[S]. Beijing:China Railway Publishing House,2019.(in Chinese))
[15] 李 楠,门玉明,高 讴,等. 微型桩群桩支护滑坡的地震动力响应研究[J]. 岩石力学与工程学报,2018,37(9):2 144–2 151.(LI Nan,MEN Yuming,GAO Ou,et al. Seismic behavior of the landslide supported by micropiles[J]. Chinese Journal of Rock Mechanics and Engineering,2018,37(9):2 144–2 151.(in Chinese))
[16] CHANG C Y,DUNCAN J M. Analysis of soil movement around a deep excavation[J]. Journal of the Soil Mechanics and Foundations Division,1970,96(5):1 655–1 681.
[17] ZHAO B,WANG Y S,WANG Y,et al. Retaining mechanism and structural characteristics of h type anti–slide pile(HTP pile) and experience with its engineering application[J]. Engineering Geology,2017,222:29–37.
[18] 中华人民共和国行业标准编写组. JGJ120—99 建筑基坑支护技术规程[S]. 北京:中国建筑工出版社,1999.(The Professional Standards Compilation Group of People's Republic of China. JGJ120 —99 Technical specification for retaining and protection of building foundation excavations[S]. Beijing:China Architecture and Building Press,1999.(in Chinese))
[19] 白 皓. 椅式桩板墙受力机制与设计计算方法研究[博士学位论文][D]. 西南交通大学,2013.(BAI Hao. Research on stress mechanism and calculation method of chair–shaped sheet–pile wall [Ph. D. Thesis][D]. Southwest Jiaotong University,2013.(in Chinese))
[20] 钱同辉,徐 华,夏文才,等. 框架式抗滑桩受力特性对比分析[J]. 中国公路学报,2012,25(6):56–59.(QIAN Tonghui,XU Hua,XIA Wencai,et al. Force analysis of framed anti-slide piles[J]. China Journal of Highway and Transport,2012,25(6):56–59.(in Chinese))
[21] 赵 波,王运生,王 羽,等. 门架式抗滑桩结构模型试验研究[J]. 土木建筑与环境工程,2017,39(1):101–105.(ZHAO Bo,WANG Yunsheng,WANG Yu,et al. Model test of the structure of portal anti–sliding piles[J]. Journal of Civil Architectural and Environmental Engineering,2017,39(1):101–105.(in Chinese))
[22] 范秋雁,许胜才,崔 峰. 一类双排桩支护结构内力计算[J]. 岩石力学与工程学报,2012,31(增1):3 152–3 158.(FAN Qiuyan,XU Shengcai,CUI Feng. Calculation for a type of retaining structure with double–row piles[J]. Chinese Journal of Rock Mechanics and Engineering,2012,31(Supp.1):3 152–3 158.(in Chinese))
[23] 王保林,姚裕春. 基于创新方法的林织铁路滑坡路堑加固结构研究[J]. 高速铁路技术,2015,6(2):15–18.(WANG Baolin,YAO Yuchun. Research on cut reinforcing structure of slide of Lindai—Zhijing rail way based on innovative approach[J]. High Speed Railway Technology,2015,6(2):15–18.(in Chinese))
[24] 中华人民共和国行业标准编写组. TB 10102—2010 铁路工程土工试验规程[S]. 北京:中国铁道出版社,2011.(The Professional Standards Compilation Group of the People's Republic of China. TB 10102—2010 Code for soil test of railway engineering[S]. Beijing:China Railway Press,2011.(in Chinese))
[25] 中华人民共和国国家标准编写组. GB 50010—2010 混凝土结构设计规范[S]. 北京:中国建筑工业出版社,2010.(The National Standards Compilation Group of the People's Republic of China. GB 50010—2010 Code for design of concrete structures[S]. Beijing:China Construction Industry Press,2010.(in Chinese))
[26] 陈伟志,蒋关鲁,刘 勇,等. 川藏铁路钻孔桩加固斜坡路基的振动台试验研究[J]. 岩石力学与工程学报,2020,39(12):2 540–2 556.(CHEN Weizhi,JIANG Guanlu,LIU Yong,et al. Shaking table test on slope subgrade reinforced by bored piles of Sichuan–Tibet railway[J]. Chinese Journal of Rock Mechanics and Engineering,2020,39(2):2 540–2 556.(in Chinese))
[27] 中华人民共和国行业标准编写组. TB 10621—2014 高速铁路设计规范[S]. 北京:中国铁道出版社,2014.(The Professional Standards Compilation Group of the People's Republic of China. TB 10621—2014 Code for design of high speed railway[S]. Beijing:China Railway Press,2014.(in Chinese))
[28] 孔祥辉,蒋关鲁,李安洪,等. 基于三维数值模拟的铁路路基动力特性分析[J]. 西南交通大学学报,2014,49(3):406–411.(KONG Xianghui,JIANG Guanlu,LI Anhong,et al. Analysis of dynamic characteristics of railway subgrade based on three-dimensional numerical simulation[J]. Journal of Southwest Jiaotong University,2014,49(3):406–411.(in Chinese))
[29] 陈伟志,李安洪,蒋关鲁,等. 铁路路基下膨胀土长短微型桩抗隆起研究[J]. 岩石力学与工程学报,2019,38(2):409–423.(CHEN Weizhi,LI Anhong,JIANG Guanlu,et al. Study on resisting upheaval of long-short micropiles of expansive soils under railway subgrade[J]. Chinese Journal of Rock Mechanics and Engineering,2019,38(2):409–423.(in Chinese))
[30] 苏 谦,黄俊杰,白 皓,等. 铁路站场岩溶地基加固补强技术与效果分析[J]. 岩土力学,2013,34(3):776–782.(SU Qian,HUANG Junjie,BAI Hao,et al. Reinforcement technique and its effect analysis of karst foundation disease of railway station[J]. Rock and Soil Mechanics,2013,34(3):776–782.(in Chinese))
[31] 冯 研,蒋关鲁,陈伟志,等. 弥勒非低矮路基超固结膨胀土地基沉降特征[J]. 中国公路学报,2018,31(5):17–25.(FENG Yan,JIANG Guanlu,CHEN Weizhi,et al. Settlement characteristics of expansive soil foundation under non-low embankment of mile[J]. China Journal of Highway and Transport,2018,31(5):17–25.(in Chinese))
[32] XIAO W,TAESEO K. New design chart for geotechnical ground improvement:characterizing cement-stabilized sand[J]. Acta Geotechnica,2020,15(3):999–1 011.
[33] 陕 耀,陆 义,周顺华,等. 有轨电车桩板结构路基与道路路基横向差异沉降离心试验研究[J]. 岩石力学与工程学报,2020,39(5):1 049–1 060.(SHAN Yao,LU Yi,ZHOU Shunhua,et al. Centrifugal model test study on lateral differential settlement between the tram pile-plank subgrade and the road subgrade[J]. Chinese Journal of Rock Mechanics and Engineering,2020,39(5):1 049–1 060.(in Chinese))
[34] KHERADI H,NAGANO K,NISHI H,et al. 1 g shaking table tests on seismic enhancement of existing box culvert with partial ground-improvement method and its 2D dynamic simulation[J]. Soils and Foundations,2018,58(3):563–581.
[35] 王进廷,杜修力,张楚汉. 瑞利阻尼介质有限元离散模型动力分析的数值稳定性[J]. 地震工程与工程振动,2002,(6):18–24.(WANG Jinting,DU Xiuli,ZHANG Chuhan. Numerical stability of explicit finite element schemes for dynamic system with Rayleigh damping[J]. Earthquake Engineering and Engineering Vibration,2002,(6):18–24.(in Chinese))
[36] 中华人民共和国国家标准编写组. GB 50111—2006 铁路工程抗震设计规范[S]. 北京:中国计划出版社,2009.(The National Standards Compilation Group of the People's Republic of China. GB 50111—2006 Code for seismic design of railway engineering[S]. Beijing:China Plan Press,2009.(in Chinese))
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2021, Vol. 40 
