近接工程对既有高铁隧道的影响及监测方法研究
|
摘要
本文依托国家高技术研究发展计划“高速铁路基础设施服役状态检测技术”项目,在归纳总结国内外各种隧道结构近接工程的基础上,根据工程实际研究了高铁隧道近接工程的影响机制及监测方法。采用数值计算、理论分析和经验类比方法,对高铁隧道近接开挖中的静力、动力问题进行了研究。
本文的主要工作内容包括以下几个方面:
(1)高速列车行驶引起的振动诱发附近结构物的响应,高铁隧道在动荷载作用下,将引起不均匀变形。采用高速列车-轨道动力相互作用模型,得到了列车振动荷载及加速度时程曲线。
(2)分别采用5m、10m、15m三种近接距离的FLAC3D模型,进行了不同近接距离下不同深度的静力开挖,得到了不同类型近接开挖对高铁隧道变形的影响机制。
(3)基于显式动力分析方法,将高速列车振动加速度时程输入到近接开挖静力计算模型中,分析了列车振动和近接开挖对高铁隧道的影响,得到了列车振动下隧道附加位移的变化规律。
(4)以数值计算典型截面位移为依据,利用隧道沉降经验公式,得到了隧道位移包络曲线,作为高铁隧道近接工程全截面变形推测及监测点设置的依据。
(5)通过高铁隧道近接工程的变形及应力计算结果分析,合理设置传感器监测点,建立高铁隧道近接工程监测系统,作为高速铁路基础设施服役状态检测系统的组成部分。
This paper depends on the "monitoring technology of high-speed railinfrastructure in the service state" project, which belongs to National HighTechnology Research and Development Program (863). Based on summarizedvarious kinds of close-spaced engineerings of tunnel structure domestic andoverseas, the impact mechanism and monitoring method of high-speed railwaytunnel are studied in a project case. The static and dynamic influence onhigh-speed railway tunnel with close-spaced excavation are carried out by usingmethods of numerical calculation, theoretical analysis and analog.
The following main researches were gained:
(1)The vibrations of high-speed train induced response in the structurearound, high-speed rail tunnel under the dynamic load will emerge non-uniformdeformation. The train vibration load and acceleration time-history curve aregained through the train-track dynamic interaction model.
(2)Three kinds of close-spaced distance5m,10m,15m were used inFLAC3D model, the models are static excavated with different depth. High-speedrailway tunnel deformation mechanism in different types of close-spacedexcavation has been presented.
(3)The high-speed train acceleration time-history is applied in staticexcavation model based on explicit dynamic analysis.High-speed rail tunnelinfluenced by the train vibration and close-spaced excavation has been analyzed,and the variation of tunnel displacement under additional vibration has been got.
(4)According to the typical cross-section displacement in numericalcalculation, the tunnel numerical calculation displacement envelope curve isobtained by settlement curve empirical formula.The curve regards as the basis offull cross-section deformation speculation and set of monitoring points.
(5)The monitoring points in the tunnel reasonably set up through high-speedrail tunnel deformation and stress analysis under close-spaced engineering.
The tunnel monitoring system has been established and served as acomponent of high-speed rail infrastructure monitoring system in the state.
本文的主要工作内容包括以下几个方面:
(1)高速列车行驶引起的振动诱发附近结构物的响应,高铁隧道在动荷载作用下,将引起不均匀变形。采用高速列车-轨道动力相互作用模型,得到了列车振动荷载及加速度时程曲线。
(2)分别采用5m、10m、15m三种近接距离的FLAC3D模型,进行了不同近接距离下不同深度的静力开挖,得到了不同类型近接开挖对高铁隧道变形的影响机制。
(3)基于显式动力分析方法,将高速列车振动加速度时程输入到近接开挖静力计算模型中,分析了列车振动和近接开挖对高铁隧道的影响,得到了列车振动下隧道附加位移的变化规律。
(4)以数值计算典型截面位移为依据,利用隧道沉降经验公式,得到了隧道位移包络曲线,作为高铁隧道近接工程全截面变形推测及监测点设置的依据。
(5)通过高铁隧道近接工程的变形及应力计算结果分析,合理设置传感器监测点,建立高铁隧道近接工程监测系统,作为高速铁路基础设施服役状态检测系统的组成部分。
This paper depends on the "monitoring technology of high-speed railinfrastructure in the service state" project, which belongs to National HighTechnology Research and Development Program (863). Based on summarizedvarious kinds of close-spaced engineerings of tunnel structure domestic andoverseas, the impact mechanism and monitoring method of high-speed railwaytunnel are studied in a project case. The static and dynamic influence onhigh-speed railway tunnel with close-spaced excavation are carried out by usingmethods of numerical calculation, theoretical analysis and analog.
The following main researches were gained:
(1)The vibrations of high-speed train induced response in the structurearound, high-speed rail tunnel under the dynamic load will emerge non-uniformdeformation. The train vibration load and acceleration time-history curve aregained through the train-track dynamic interaction model.
(2)Three kinds of close-spaced distance5m,10m,15m were used inFLAC3D model, the models are static excavated with different depth. High-speedrailway tunnel deformation mechanism in different types of close-spacedexcavation has been presented.
(3)The high-speed train acceleration time-history is applied in staticexcavation model based on explicit dynamic analysis.High-speed rail tunnelinfluenced by the train vibration and close-spaced excavation has been analyzed,and the variation of tunnel displacement under additional vibration has been got.
(4)According to the typical cross-section displacement in numericalcalculation, the tunnel numerical calculation displacement envelope curve isobtained by settlement curve empirical formula.The curve regards as the basis offull cross-section deformation speculation and set of monitoring points.
(5)The monitoring points in the tunnel reasonably set up through high-speedrail tunnel deformation and stress analysis under close-spaced engineering.
The tunnel monitoring system has been established and served as acomponent of high-speed rail infrastructure monitoring system in the state.
引文
[1]仇文革.地下工程施工力学原理与对策的研究[D].成都:西南交通大学博士论文,2003.
[2]李晓红,王宏图,贾剑青等.隧道及地下工程围岩稳定性及可靠性分析的极限位移判别[J].岩土力学,2005,26(6):850-854.
[3]倪绍虎,肖明.基于围岩松动圈的地下工程参数场位移反分析[J].岩石力学与工程学报,2009,28(7):1439-1445.
[4]姚燕明,孙巍.深基坑开挖对共用连续墙的既有车站结构内力影响的空间分析[J].岩土工程学报,2006,28(增刊):1411-1414.
[5]于松,许抒.既有地铁车站结构单侧卸载工况下的变形控制技术[J].建筑施工,2008,30(5):352-355.
[6]贾颖绚,刘维宁,刘卫丰.北京地下联络线运营列车振动对既有地铁结构的影响[J].中国铁道科学,2008,29(5):72-75.
[7]黄强兵.地裂缝对地铁隧道的影响机制及病害控制研究[J].岩石力学与工程学报,2009,28(10):1356-1361.
[8]高盟,高广运,冯世进等.基坑开挖引起紧贴运营地铁车站的变形控制究[J].岩土工程学报,2008,30(6):818-823.
[9]孔祥鹏,刘国彬,廖少明.明珠线二期上海体育馆地铁车站穿越施工对地铁一号线车站的影响[J].岩石力学与工程学报,2004,23(5):821-825.
[10]周春玲.基坑邻近开挖对地铁隧道的影响分析[D].广州:华南理工大学,2009.
[11]刘泉声,徐光苗,张志凌.光纤测量技术在岩土工程中的应用[J].岩石力学与工程学报,2004,23(2):310-314.
[12]郭玉彬,葛璜.光纤Bragg光栅的研究[J].光学精密工程,1999,7(1):31-38.
[13] Muralidhar Lanka, Alley Butler, Raymond Sterling. Use of approximatereasoning techniques for locating underground utilities[J]. Tunnelling andUnderground Space Technology,2002(1):S13-S31.
[14]贺跃光,杜年春,李志伟.基于Web GIS的城市地铁施工监测信息管理系统研究[J].岩土力学,2009,30(1):265-268.
[15]牛大伟.地铁施工穿越既有线监控量测与施工方案优化[D].北京:北京工业大学.2009.
[16] Martin Adersen, Berg, et al. Development of an Optical Monitoring Systemfor Flexible Risers[J]. NKT Flexibles, OTC13201,2001.
[17]邵华,张子新.盾构近距离穿越施工对已运营隧道的扰动影响分析[J].岩土力学,2004,25(增刊):545-549.
[18] Nikles, M. et al. Greatly extended distance pipeline monitoring using fiberoptics[J]. Proceedings of the International Conference on OffshoreMechanics and Arctic Engineering-OMAE, v3, Proceedings of the24thInternational Conference on Offshore Mechanics and Arctic Engineering,2005OMAE,2005:539-546.
[19]刘东海,刘军,萧岩等.盾构隧道斜交下穿地铁车站的影响与监测研究[J].岩石力学与工程学报,2009,28(增1):3186-3191.
[20]吴钰骅,沈林冲,金伟良.长距离光纤传感技术在地铁隧道监测中的应用[J].中国市政工程,2006(6):59-61.
[21] Frank Stajano, Neil Hoult, Ian Wassell. Smart bridges, smart tunnels:Transforming wireless sensor networks from research prototypes into robustengineering infrastructure[J]. Ad Hoc Networks, In Press, Corrected Proof,Available online16April2010.
[22]孙新民,孙红月,严细水.FBG传感器在量测围岩内部位移中的应用[J].岩石力学与工程学报,2008,增2:3847-3851.
[23] Manoj Kumar, R.A. Shenoi, S.J. Cox. Experimental validation of modalstrain energies based damage identification method for a compositesandwich beam[J]. Composites Science and Technology,2009(69):1635-1643.
[24]蔡明,P. K. Kaiser L, Cotesta A. Dasys.共通地质模型和虚拟现实在地下工程规划与设计中的应用[J].岩石力学与工程学报,2006,25(6):1182-1189.
[25]李仲奎,王爱民,王克等.地下工程三维地质力学模型制作逆向控制技术研究与应用[J].岩石力学与工程学报,2009,28(9):1729-1734.
[26]包太,税月.MMF生长模型在隧道监测数据分析中的应用研究[J].贵州大学学报(自然科学版),2009,26(4):131-133.
[27] H.S.B. Duzgun, H.H. Einstein. Assessment and management of roof fallrisks in underground coal mines[J]. Safety Science,2004,42(1):23-41.
[28] Norhisham Bakhary, Hong Hao, Andrew J. Deeks. Damage detection usingartificial neural network with consideration of uncertainties[J]. EngineeringStructures,2007(29):2806-2815.
[29] M. Chandrashekhar, RanjanGanguli. Damage assessment of structures withuncertainty by using mode-shape curvatures and fuzzy logic[J]. Journal ofSound and Vibration,2009(326):939-957.
[30] Ricardo Perera, Antonio Ruiz, Carlos Manzano. An evolutionarymultiobjective framework for structural damage localization andquantification[J]. Engineering Structures,2007(29):2540-2550.
[31] Sheng-En Fang, Ricardo Perera. Damage identification by response surfacebased model updating using D-optimal design[J]. Mechanical Systems andSignal Processing,2011(25):717-733.
[32] L. Jing. A reviewof techniques, advances and outstanding issues innumerical modelling for rock mechanics and rock engineering[J].International Journal of Rock Mechanics&Mining Sciences,2003(40):283-353.
[33] Manolis Papadrakakis, Vissarion Papadopoulos, Nikos D. Lagaros.Vulnerability analysis of large concrete dams using the continuum strongdiscontinuity approach and neural networks[J]. Structural Safety,2008(30):217-235.
[34] K. Worden, A.P. Burrows. Optimal sensor placement for fault detection [J].Engineering Structures,2001(23):885-901.
[35]刘晶波,谷音,杜义欣.一致粘弹性人工边界及粘弹性边界单元[J].岩土工程学报,2006,28(9):1070-1075.
[36]董亮,赵成刚,蔡德钩等.高速铁路路基的动力响应分析方法[J].工程力学,2008,25(11):231-236.
[37]马学宁,梁波,高峰.高速铁路板式无砟轨道-路基结构动力特性研究[J].铁道科学,2011,33(2):72-76.
[38]陈雪华,律文田,王永和.高速铁路路桥过渡段路基动响应特性研究[J].振动与冲击,2006,25(3):95-98.
[39]董亮,叶阳升,蔡德钩等.高速铁路软土地基处理方法对比试验[J].岩土力学,2006,27(10):1856-1860.
[40]王智猛,蒋关鲁,魏永幸等.高速铁路基床现场循环加载试验研究[J].岩土力学,2010,31(3):760-763.
[41]梁波,罗红,孙常新.高速铁路振动荷载的模拟研究[J].铁道学报,2006,28(4):89-94.
[42]何川,张志强.地铁区间盾构隧道对周边建筑物结构基础影响分析[J].现代隧道技术,2004(增刊):249-255.
[43]吴祖标,彭立敏,张忠.浏阳河隧道互通立交桥段邻近施工问题的数值分析[J].岩土力学,2008,29(5):1120-1126.
[44]赵则超.立体交叉隧道不同近接距离对围岩压力和衬砌结构力学行为的影响[D].成都:西南交通大学硕士论文,2009.
[45]龚伦,仇文革.既有铁路隧道受下穿引水隧洞近接施工影响预测[J].中国铁道科学,2007,28(4):30-33.
[46]周太全,华渊,吕宝华.金华山软岩铁路隧道施工过程围岩屈服接近度分析[J].工程地质学报,2008,16(4):546-550.
[47]龚伦.上下交叉隧道近接施工力学原理及对策研究[D].成都:西南交通大学博士论文,2007.
[48]郭宏博.上下交叉隧道近接施工影响分区研究[D].成都:西南交通大学硕士论文,2008.
[49]中华人民共和国交通部.JDGD70-2004公路隧道设计规范[S].北京:人民交通出版社,2004.
[50]中华人民共和国铁道部.TB1003-2005铁路隧道设计规范[S].北京:中国铁道出版社,2005.
[51]中华人民共和国建设部.GB50218-94工程岩体分级标准[S].北京:建设部标准定额研究所,1994.
[52]潘昌实,刘维宁.东坡隧道列车振动响应分析研究[J].兰州铁道学院学报,1989:169-175.
[53]潘昌实,谢正光.地铁区间隧道列车振动测试与分析[J].土木工程学报,1990,23(2):21-28.
[54]陈实,徐国彬,高日.列车振动对铁路沿线结构物影响的动力分析[J].北方交通大学学报,1998,22(4):57-60.
[55]毕湘利,周顺华.列车振动荷载对邻近深基坑的既有站变形影响[J].同济大学学报(自然科学版),2004,32(12):1599-1602.
[56]贾颖绚,郭猛,刘维宁等.列车振动荷载对古建筑的动力影响[J].北京交通大学学报,2009,33(1):118-122.
[57]张玉娥,白宝鸿.高速铁路隧道列车振动响应数值分析方法[J].振动与冲击,2001,20(3):91-93.
[58]梁波.高速铁路路基的动力特性及土工合成材料的应用研究[D].成都:西南交通大学博士论文,1998.
[59] Eason G. The Stresses Produced in a Semi-Infinite Solid by a MovingSurface Force[J]. International Journal of Engineering Sciences,1965(2):581-609.
[60] Fryba L. Vibration of Solids and Structures under Moving Load[M].TheNetherlands:Noordhoff International Publishing,1972.
[2]李晓红,王宏图,贾剑青等.隧道及地下工程围岩稳定性及可靠性分析的极限位移判别[J].岩土力学,2005,26(6):850-854.
[3]倪绍虎,肖明.基于围岩松动圈的地下工程参数场位移反分析[J].岩石力学与工程学报,2009,28(7):1439-1445.
[4]姚燕明,孙巍.深基坑开挖对共用连续墙的既有车站结构内力影响的空间分析[J].岩土工程学报,2006,28(增刊):1411-1414.
[5]于松,许抒.既有地铁车站结构单侧卸载工况下的变形控制技术[J].建筑施工,2008,30(5):352-355.
[6]贾颖绚,刘维宁,刘卫丰.北京地下联络线运营列车振动对既有地铁结构的影响[J].中国铁道科学,2008,29(5):72-75.
[7]黄强兵.地裂缝对地铁隧道的影响机制及病害控制研究[J].岩石力学与工程学报,2009,28(10):1356-1361.
[8]高盟,高广运,冯世进等.基坑开挖引起紧贴运营地铁车站的变形控制究[J].岩土工程学报,2008,30(6):818-823.
[9]孔祥鹏,刘国彬,廖少明.明珠线二期上海体育馆地铁车站穿越施工对地铁一号线车站的影响[J].岩石力学与工程学报,2004,23(5):821-825.
[10]周春玲.基坑邻近开挖对地铁隧道的影响分析[D].广州:华南理工大学,2009.
[11]刘泉声,徐光苗,张志凌.光纤测量技术在岩土工程中的应用[J].岩石力学与工程学报,2004,23(2):310-314.
[12]郭玉彬,葛璜.光纤Bragg光栅的研究[J].光学精密工程,1999,7(1):31-38.
[13] Muralidhar Lanka, Alley Butler, Raymond Sterling. Use of approximatereasoning techniques for locating underground utilities[J]. Tunnelling andUnderground Space Technology,2002(1):S13-S31.
[14]贺跃光,杜年春,李志伟.基于Web GIS的城市地铁施工监测信息管理系统研究[J].岩土力学,2009,30(1):265-268.
[15]牛大伟.地铁施工穿越既有线监控量测与施工方案优化[D].北京:北京工业大学.2009.
[16] Martin Adersen, Berg, et al. Development of an Optical Monitoring Systemfor Flexible Risers[J]. NKT Flexibles, OTC13201,2001.
[17]邵华,张子新.盾构近距离穿越施工对已运营隧道的扰动影响分析[J].岩土力学,2004,25(增刊):545-549.
[18] Nikles, M. et al. Greatly extended distance pipeline monitoring using fiberoptics[J]. Proceedings of the International Conference on OffshoreMechanics and Arctic Engineering-OMAE, v3, Proceedings of the24thInternational Conference on Offshore Mechanics and Arctic Engineering,2005OMAE,2005:539-546.
[19]刘东海,刘军,萧岩等.盾构隧道斜交下穿地铁车站的影响与监测研究[J].岩石力学与工程学报,2009,28(增1):3186-3191.
[20]吴钰骅,沈林冲,金伟良.长距离光纤传感技术在地铁隧道监测中的应用[J].中国市政工程,2006(6):59-61.
[21] Frank Stajano, Neil Hoult, Ian Wassell. Smart bridges, smart tunnels:Transforming wireless sensor networks from research prototypes into robustengineering infrastructure[J]. Ad Hoc Networks, In Press, Corrected Proof,Available online16April2010.
[22]孙新民,孙红月,严细水.FBG传感器在量测围岩内部位移中的应用[J].岩石力学与工程学报,2008,增2:3847-3851.
[23] Manoj Kumar, R.A. Shenoi, S.J. Cox. Experimental validation of modalstrain energies based damage identification method for a compositesandwich beam[J]. Composites Science and Technology,2009(69):1635-1643.
[24]蔡明,P. K. Kaiser L, Cotesta A. Dasys.共通地质模型和虚拟现实在地下工程规划与设计中的应用[J].岩石力学与工程学报,2006,25(6):1182-1189.
[25]李仲奎,王爱民,王克等.地下工程三维地质力学模型制作逆向控制技术研究与应用[J].岩石力学与工程学报,2009,28(9):1729-1734.
[26]包太,税月.MMF生长模型在隧道监测数据分析中的应用研究[J].贵州大学学报(自然科学版),2009,26(4):131-133.
[27] H.S.B. Duzgun, H.H. Einstein. Assessment and management of roof fallrisks in underground coal mines[J]. Safety Science,2004,42(1):23-41.
[28] Norhisham Bakhary, Hong Hao, Andrew J. Deeks. Damage detection usingartificial neural network with consideration of uncertainties[J]. EngineeringStructures,2007(29):2806-2815.
[29] M. Chandrashekhar, RanjanGanguli. Damage assessment of structures withuncertainty by using mode-shape curvatures and fuzzy logic[J]. Journal ofSound and Vibration,2009(326):939-957.
[30] Ricardo Perera, Antonio Ruiz, Carlos Manzano. An evolutionarymultiobjective framework for structural damage localization andquantification[J]. Engineering Structures,2007(29):2540-2550.
[31] Sheng-En Fang, Ricardo Perera. Damage identification by response surfacebased model updating using D-optimal design[J]. Mechanical Systems andSignal Processing,2011(25):717-733.
[32] L. Jing. A reviewof techniques, advances and outstanding issues innumerical modelling for rock mechanics and rock engineering[J].International Journal of Rock Mechanics&Mining Sciences,2003(40):283-353.
[33] Manolis Papadrakakis, Vissarion Papadopoulos, Nikos D. Lagaros.Vulnerability analysis of large concrete dams using the continuum strongdiscontinuity approach and neural networks[J]. Structural Safety,2008(30):217-235.
[34] K. Worden, A.P. Burrows. Optimal sensor placement for fault detection [J].Engineering Structures,2001(23):885-901.
[35]刘晶波,谷音,杜义欣.一致粘弹性人工边界及粘弹性边界单元[J].岩土工程学报,2006,28(9):1070-1075.
[36]董亮,赵成刚,蔡德钩等.高速铁路路基的动力响应分析方法[J].工程力学,2008,25(11):231-236.
[37]马学宁,梁波,高峰.高速铁路板式无砟轨道-路基结构动力特性研究[J].铁道科学,2011,33(2):72-76.
[38]陈雪华,律文田,王永和.高速铁路路桥过渡段路基动响应特性研究[J].振动与冲击,2006,25(3):95-98.
[39]董亮,叶阳升,蔡德钩等.高速铁路软土地基处理方法对比试验[J].岩土力学,2006,27(10):1856-1860.
[40]王智猛,蒋关鲁,魏永幸等.高速铁路基床现场循环加载试验研究[J].岩土力学,2010,31(3):760-763.
[41]梁波,罗红,孙常新.高速铁路振动荷载的模拟研究[J].铁道学报,2006,28(4):89-94.
[42]何川,张志强.地铁区间盾构隧道对周边建筑物结构基础影响分析[J].现代隧道技术,2004(增刊):249-255.
[43]吴祖标,彭立敏,张忠.浏阳河隧道互通立交桥段邻近施工问题的数值分析[J].岩土力学,2008,29(5):1120-1126.
[44]赵则超.立体交叉隧道不同近接距离对围岩压力和衬砌结构力学行为的影响[D].成都:西南交通大学硕士论文,2009.
[45]龚伦,仇文革.既有铁路隧道受下穿引水隧洞近接施工影响预测[J].中国铁道科学,2007,28(4):30-33.
[46]周太全,华渊,吕宝华.金华山软岩铁路隧道施工过程围岩屈服接近度分析[J].工程地质学报,2008,16(4):546-550.
[47]龚伦.上下交叉隧道近接施工力学原理及对策研究[D].成都:西南交通大学博士论文,2007.
[48]郭宏博.上下交叉隧道近接施工影响分区研究[D].成都:西南交通大学硕士论文,2008.
[49]中华人民共和国交通部.JDGD70-2004公路隧道设计规范[S].北京:人民交通出版社,2004.
[50]中华人民共和国铁道部.TB1003-2005铁路隧道设计规范[S].北京:中国铁道出版社,2005.
[51]中华人民共和国建设部.GB50218-94工程岩体分级标准[S].北京:建设部标准定额研究所,1994.
[52]潘昌实,刘维宁.东坡隧道列车振动响应分析研究[J].兰州铁道学院学报,1989:169-175.
[53]潘昌实,谢正光.地铁区间隧道列车振动测试与分析[J].土木工程学报,1990,23(2):21-28.
[54]陈实,徐国彬,高日.列车振动对铁路沿线结构物影响的动力分析[J].北方交通大学学报,1998,22(4):57-60.
[55]毕湘利,周顺华.列车振动荷载对邻近深基坑的既有站变形影响[J].同济大学学报(自然科学版),2004,32(12):1599-1602.
[56]贾颖绚,郭猛,刘维宁等.列车振动荷载对古建筑的动力影响[J].北京交通大学学报,2009,33(1):118-122.
[57]张玉娥,白宝鸿.高速铁路隧道列车振动响应数值分析方法[J].振动与冲击,2001,20(3):91-93.
[58]梁波.高速铁路路基的动力特性及土工合成材料的应用研究[D].成都:西南交通大学博士论文,1998.
[59] Eason G. The Stresses Produced in a Semi-Infinite Solid by a MovingSurface Force[J]. International Journal of Engineering Sciences,1965(2):581-609.
[60] Fryba L. Vibration of Solids and Structures under Moving Load[M].TheNetherlands:Noordhoff International Publishing,1972.