基坑复合土钉支护的室内模型试验及数值模拟研究
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摘要
在城市建设迅速发展,大量超高层建筑及地下空间的兴建与开发过程中,为满足建筑结构使用功能的各项要求,基坑开挖深度越来越深、面积越来越大。
施工快捷、经济可靠的土钉支护技术在基坑工程中得到广泛的应用。然而单纯的土钉支护不适用于地下水位较高、淤泥质土等不良土质中。近年来在土钉支护的基础上发展出预应力锚杆(锚索)、土钉与水泥土搅拌桩、超前微桩等支护形式相结合的复合型土钉支护。复合土钉支护技术能够针对不同的地质条件灵活组合。但目前对复合土钉支护工作机理的研究不够深入,在工程中经常为保证基坑的安全稳定,人为提高基坑支护的安全系数,这样导致材料浪费,同时出现基坑失稳的工程事故还时有发生。
本文结合某基坑实际工程,运用相似理论对室内模型试验进行设计,用MIDAS/GTS进行数值模拟,进一步通过工程监测数据对预应力锚杆复合土钉支护的工作机理进行研究,所得结论对类似工程的设计与施工有一定参考价值:
(1)不同支护体系中土钉和预应力锚杆所受轴力的传递与分布规律;
(2)不用施工阶段基坑水平位移均出现鼓肚子现象,最大水平位移发生在基坑的中下部;
(3)预应力锚杆锚固段轴力为曲线分布,轴力随开挖深度增大。最大轴力出现在与自由段相连的地方,逐渐减小至远端最小。
With the rapid development of city construction, large number of high-rise buildingconstruction and municipal underground space development, in order to meet the needs ofbuilding structure and the use of functional requirements, excavation depth is more and moredeeper, and the growing area.
Soil nailing is a kind of economic and reliable, fast construction foundation bracing infoundation engineering technology, a large number of applications received. But the soilnailing support cannot be used for silt soil and other bad soil, underground water level and onthe deformation control strictly in foundation engineering. In recent years, soil nailing isdeveloped on the basis of soil nailing and cement soil mixing pile, prestressed anchor bolt,advanced micro pile supporting forms combining composite soil nailing support. Compositesoil nailing technology can be targeted at different sites and geological condition, suit one'smeasures to local conditions, flexible combination. But the composite soil nailing workingmechanism research is not deep enough, resulting in engineering is often appear in order toensure the safety and stability of the foundation, foundation support design personnel tocontinuously improve the safety coefficient, causing material waste; on the other hand,because the instability of foundation and the deformation caused by the engineering accidentbut when have happened.
Combined with the actual project, using similarity theory to the indoor model test designstudy. And the prestressed anchor composite soil nailing by MIDAS / GTS finite analysissoftware for numerical simulation and engineering monitoring and contrast. The prestressedanchor composite soil nailing were studied thoroughly, the conclusion to the similarengineering design has a certain reference value:
(1) Different modes of arrangement, in the supporting system of soil nailing and anchorthe axial force transmission and distribution;
(2) Each construction stage, foundation horizontal displacement curve will appear" drumbelly" phenomenon, the maximum horizontal displacement of foundation is occurred, not thetop;
(3) Prestressed anchor section of the axial force and the free section are connected tolocal maximum, minimum variation in the distal, axial force distribution curve, and with theincrease of depth of excavation.
施工快捷、经济可靠的土钉支护技术在基坑工程中得到广泛的应用。然而单纯的土钉支护不适用于地下水位较高、淤泥质土等不良土质中。近年来在土钉支护的基础上发展出预应力锚杆(锚索)、土钉与水泥土搅拌桩、超前微桩等支护形式相结合的复合型土钉支护。复合土钉支护技术能够针对不同的地质条件灵活组合。但目前对复合土钉支护工作机理的研究不够深入,在工程中经常为保证基坑的安全稳定,人为提高基坑支护的安全系数,这样导致材料浪费,同时出现基坑失稳的工程事故还时有发生。
本文结合某基坑实际工程,运用相似理论对室内模型试验进行设计,用MIDAS/GTS进行数值模拟,进一步通过工程监测数据对预应力锚杆复合土钉支护的工作机理进行研究,所得结论对类似工程的设计与施工有一定参考价值:
(1)不同支护体系中土钉和预应力锚杆所受轴力的传递与分布规律;
(2)不用施工阶段基坑水平位移均出现鼓肚子现象,最大水平位移发生在基坑的中下部;
(3)预应力锚杆锚固段轴力为曲线分布,轴力随开挖深度增大。最大轴力出现在与自由段相连的地方,逐渐减小至远端最小。
With the rapid development of city construction, large number of high-rise buildingconstruction and municipal underground space development, in order to meet the needs ofbuilding structure and the use of functional requirements, excavation depth is more and moredeeper, and the growing area.
Soil nailing is a kind of economic and reliable, fast construction foundation bracing infoundation engineering technology, a large number of applications received. But the soilnailing support cannot be used for silt soil and other bad soil, underground water level and onthe deformation control strictly in foundation engineering. In recent years, soil nailing isdeveloped on the basis of soil nailing and cement soil mixing pile, prestressed anchor bolt,advanced micro pile supporting forms combining composite soil nailing support. Compositesoil nailing technology can be targeted at different sites and geological condition, suit one'smeasures to local conditions, flexible combination. But the composite soil nailing workingmechanism research is not deep enough, resulting in engineering is often appear in order toensure the safety and stability of the foundation, foundation support design personnel tocontinuously improve the safety coefficient, causing material waste; on the other hand,because the instability of foundation and the deformation caused by the engineering accidentbut when have happened.
Combined with the actual project, using similarity theory to the indoor model test designstudy. And the prestressed anchor composite soil nailing by MIDAS / GTS finite analysissoftware for numerical simulation and engineering monitoring and contrast. The prestressedanchor composite soil nailing were studied thoroughly, the conclusion to the similarengineering design has a certain reference value:
(1) Different modes of arrangement, in the supporting system of soil nailing and anchorthe axial force transmission and distribution;
(2) Each construction stage, foundation horizontal displacement curve will appear" drumbelly" phenomenon, the maximum horizontal displacement of foundation is occurred, not thetop;
(3) Prestressed anchor section of the axial force and the free section are connected tolocal maximum, minimum variation in the distal, axial force distribution curve, and with theincrease of depth of excavation.
引文
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[22]陈福全,马时东.土钉加固边坡的离心模型试验与分析[J].工业建筑,1999,29(9):12-15.
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[37]黄永来.预应力锚索复合土钉在深基坑支护中的加固应用[J].科技传播,2010,(7).
[38]阮长锋,孙富学.软土基坑复合土钉支护有限元分析[J].中国水运,2010,10(4).
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[43]李德寅,王邦媚,林亚超.结构模型试验[M].北京:科学出版社,1996.
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[2]龚晓南,高有潮.深基坑工程设计施工手册[M].北京:中国建筑工业出版社,1998.
[3] Robert W.Day. Foundation Engineering Handbook[M]. NewYork: McGRAW-HILLCompanies, Inc.
[4]侯学渊,顾尧章.高层建筑的岩土工程问题[M].杭州:浙江大学出版社,1994.
[5]侯学渊,刘国彬,黄院雄.城市基坑工程发展的几点看法[J].施工技术,2000,29(1):5-7.
[6]黄强.深基坑支护工程设计技术[M].北京:中国建筑工业出版社,2001.
[7]曾宪明,林润德,易平.基坑与边坡事故警示录[M].北京:中国建筑工业出版社,1999.
[8]唐业清,李启民,崔江余.基坑工程事故分析与处理[M].北京:中国建筑工业出版社,1999.
[9]龚晓南.土钉和复合土钉支护若干问题[J].土木工程学报,2003,36(10):80-83.
[10] Bruce D A, Jewell R A. Soil Nailing Application and Practice[J], Part. GroundEngineering, 1991, 11.
[11]中华人民共和国行业标准.建筑基坑支护技术规程(JGJ120-99)[S].北京:中国建筑工业出版社,1999.
[12] Scientific Committee of the French National Project CLOUTERRE(President:Schlosser)Recommendations CLOUTERRE 1991 for Designing, Calculating, Constructing andInspecting Earth Support Systems Using Soil Nailing, FHWA/SA-93/026, 1993.
[13]张明聚.土钉支护工作性能的研究[D].北京:清华大学,2000.
[14]王步云,高顺峰.土钉技术在边坡稳定中的应用[J].煤矿设计,1990,(10).
[15]王立峰,朱向荣.土钉墙支护结构技术研究进展[J].工业建筑,2006,36(S1):637-641.
[16] Juran I, Baudrand G. Design of Soil Nail Retaining Structures[J]. Geotechnical SpecialPublication, ASCE, 1990, No.25:654-659.
[17]陈利洲,李象范,莫暖娇.土钉墙钉长确定和整体稳定性[J].上海地质,1999,(3).
[18] J.S.Kim, J.Y.KIM and S.R.Lee. Analysis of Soil Nailed Earth Slope by Discrete ElementMethod[J]. Computers and Geotechnics, Vol.20, No.1, 1997.
[19] Schlosser, F&Unerreiner, P. French Research Program Clouterre on Soil Nailing[J].Getechnical Special Publication, ASCE, 1992, 30(2):739-749.
[20] Byrne R.J, Walkingshaw JL. FHWA International Scanning Tour for Geotechnology[J],September-October 1992, FHWA/PL-93/020 June 1993.
[21] Shen. C.K., Hernnan. L.R.. Bang. S. An in-situ Earth Reinforcement Lateral SupportSystem[J]. Dept. of Civil Engineering Universiy of California, Davis. Report No.81-03,1981.
[22]陈福全,马时东.土钉加固边坡的离心模型试验与分析[J].工业建筑,1999,29(9):12-15.
[23]莫暖娇,何之民,陈利州.土钉墙模型试验分析[J].上海地质,1999,(3):47-49.
[24] Stocker M.F. Soil Nailing, Proc.Int.Conf. On Soil Reinforcement[M], Paris, 1979.
[25] Elias, V. &Juran, I. Soil Nailing for Stabilization of Highway Slopes and Excavations[J].FHWA/RD-89/198, Jun 1991, 868-905.
[26] Bridle A.D. Soil Nailing Analysis and Design. Ground Engineering[M], 1989.
[27]程良奎,杨志银.土钉墙技术的研究与应用[M].岩土锚固工程技术,北京:人民交通出版社,1996:21-27.
[28]张明聚,宋二祥,陈肇元.土钉支护设计的修正条分法[J].工程勘察,1997,14(6):1-5.
[29]陈昌富,朱剑锋,龚晓南.基于响应面法和Morgenstern-Price法土坡可靠度计算方法[J].工程力学,2008,25(10):166-172.
[30] Smith I M and Su N. Three-dimensional FE analysis of a nailed soil wall curved inplan[J]. Int.J.Numer.Anal.Meth.Geomech, 1997, 21:583-597.
[31]崔岩,张鑫.深基坑土钉支护的有限元分析[J].工程力学,1996,13(2):103-109.
[32]张明聚,陈肇元,宋二祥.深基坑土钉支护有限元分析方法及应用[J].工业建筑,1999,29(9):7-15.
[33]胡孔国,宋启根.土钉墙作用机理的非线性分析[J].工业建筑,1997,27(11):10-13.
[34]杜长学.钻孔注浆土钉在深基坑支护工程中的应用[J].勘察技术,中国有色金属工业长沙勘察院,1997,2.
[35]闫莫明,徐祯祥,苏自约.岩土锚固技术手册[M].北京:人们交通出版社,2004,5.
[36]林希强.基坑复合土钉支护全过程内力及变形研究[D].北京:中国地质大学博士论文,2003.
[37]黄永来.预应力锚索复合土钉在深基坑支护中的加固应用[J].科技传播,2010,(7).
[38]阮长锋,孙富学.软土基坑复合土钉支护有限元分析[J].中国水运,2010,10(4).
[39]杨林德,李象范,钟正雄.复合型土钉墙的非线性有限元分析[J].岩土工程学报,2001,23(2):149-152.
[40]宋二祥,邱明.基坑复合土钉支护的有限元分析[J].岩土力学,2001,22(3):241-245.
[41]肖毅,邹勇,俞季民.钉锚结合支护的模型试验研究[J].武汉水利电力大学学报,1999,32(1):73-77.
[42]贾金青.深基坑预应力锚杆柔性支护法的理论及实践[M].北京:中国建筑工业出版社,2006.
[43]李德寅,王邦媚,林亚超.结构模型试验[M].北京:科学出版社,1996.
[44] [日]江守一郎等著,蒋彭年等译.模型试验的理论和应用[M].北京:科学出版社,1984.
[45]左东启.模型试验的理论和方法[M].北京:水利电力出版社,1984.
[46]郭廷伟,李安定译.模型实验的理论和应用[M].北京:科学出版社,1984.
[47]徐挺.相似理论与模型实验[M].北京:农业出版社,1982.
[48]南京水利科学研究院.《土工试验规程》SL237-1999[S].北京:中国水利水电出版社,1999.
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