边坡加固方案的优化设计
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摘要
边坡工程涉及到国民经济建设的各个方面,如露天采矿工程、铁路、公路、水利建设、房屋建筑与市政建设等等,它一方面关系到其所维系的各种构筑物的安全与正常使用,另一方面又影响到构筑物的建设成本。随着人口的急速增长和土地资源的过度开发,边坡问题已变成同地震和火山相并列的全球性三大地质灾害之一。
在公路方面,长期以来,路基边坡的治理一直是高速公路建设中的一个薄弱环节,在20世纪80年代中期以前,我国主要以低等级公路建设为主,由于交通量小,线路选择时深挖高填较少,加之投资不大,因而边坡治理工程不作为公路建设的主体工程,甚至在工程中对边坡的治理研究常常被忽视。20世纪80年代以来,随着我国公路建设的飞速发展,边坡稳定性问题日益突出,但由于缺乏对边坡治理技术的系统研究,从而为工程埋下隐患,边坡失稳将造成交通中断,甚至造成巨大的经济损失和不良的社会影响,同时大大增加了后期维护处治费用。因此,对于一个具体的边坡,在选择支挡方案时,如何进行有效地支护,并且尽可能地降低工程造价,即对边坡加固方案进行优化设计,这是需要考虑的首要问题。
本文阐述了各种边坡加固技术的设计原理与适用条件;归纳总结了边坡分类及其加固方案的选择方法;并通过对锚杆(索)作用机理的分析,以锚固角作为关键因子,推导最优化锚固角和最大抗滑力锚固角计算公式;此外运用有限单元法,计算出边坡内部各点的应力、位移和塑性区,用强度折减法对边坡进行稳定性评价。
同时,结合云南某高速公路边坡处治的实际工程,运用上述的理论和方法对K47+475~K47+630右侧边坡加固进行了优化设计,力争做到使用上安全可靠、施工技术上简便可行、经济上合理。
Slope engineering relates to all aspects of national economic construction, such as the open air mining engineering, railroad, highway, water conservancy, construction engineering and civil construction. On one hand it determines the safety and in gear use of all constructions which it support, on the other hand it influences the cost of the building. With the quick increasing of population and excess exploitation of land resource, slope problem has been one of the three biggest geological disasters and the other two are earthquake and volcano.
The disposal of roadbed and slope is a weakness in freeway construction for a long time. In the metaphase of 1980's, our highway construction mostly give priority to low grade road. For the low traffic and small investment, deep digging and high filling are infrequent. So slope retaining engineering is not the principal engineering in highway construction and even be neglected. With the rapid development of highway construction, slope stability problem stands out increasingly in recent three decades. But being short of slope retaining research by the numbers, there are a lot of hidden dangers in highway construction. Once slopes lose their stability, the landslide will interrupt the traffic and even result in huge economic loss and bring on bad social influences. At the same time, it will greatly increase the evening slope retaining expense. Therefore, how to reinforce slopes efficiently and try our best to reduce the engineering cost for a practical slope when we select retaining project is very important.
In an other word, optimum design for slope retaining project is a principal considered problem.
This paper expatiates the design principle and apply condition of all kinds of slope retaining technology; summarizes slope class and the methods how to select slope reinforcement project; indicates the key factor of anchoring angle through the analysis of the anchoring mechanism, deduce the formula for the optimum and the maximum slide resistant anchoring angles respectively; analyze slope stability by finite element method and calculate stress, displacement, plastic zone through
c- reduction algorithm.
Furthermore, in combination with a practical slope engineering which lies in one freeway in Yunnan province, this paper use the upper theory and methods to carry out the optimum design for slope reinforcement project for a practical slope which lies the right side of K47+475-K47+630, and try to make this engineering safe, feasible and economical.
在公路方面,长期以来,路基边坡的治理一直是高速公路建设中的一个薄弱环节,在20世纪80年代中期以前,我国主要以低等级公路建设为主,由于交通量小,线路选择时深挖高填较少,加之投资不大,因而边坡治理工程不作为公路建设的主体工程,甚至在工程中对边坡的治理研究常常被忽视。20世纪80年代以来,随着我国公路建设的飞速发展,边坡稳定性问题日益突出,但由于缺乏对边坡治理技术的系统研究,从而为工程埋下隐患,边坡失稳将造成交通中断,甚至造成巨大的经济损失和不良的社会影响,同时大大增加了后期维护处治费用。因此,对于一个具体的边坡,在选择支挡方案时,如何进行有效地支护,并且尽可能地降低工程造价,即对边坡加固方案进行优化设计,这是需要考虑的首要问题。
本文阐述了各种边坡加固技术的设计原理与适用条件;归纳总结了边坡分类及其加固方案的选择方法;并通过对锚杆(索)作用机理的分析,以锚固角作为关键因子,推导最优化锚固角和最大抗滑力锚固角计算公式;此外运用有限单元法,计算出边坡内部各点的应力、位移和塑性区,用强度折减法对边坡进行稳定性评价。
同时,结合云南某高速公路边坡处治的实际工程,运用上述的理论和方法对K47+475~K47+630右侧边坡加固进行了优化设计,力争做到使用上安全可靠、施工技术上简便可行、经济上合理。
Slope engineering relates to all aspects of national economic construction, such as the open air mining engineering, railroad, highway, water conservancy, construction engineering and civil construction. On one hand it determines the safety and in gear use of all constructions which it support, on the other hand it influences the cost of the building. With the quick increasing of population and excess exploitation of land resource, slope problem has been one of the three biggest geological disasters and the other two are earthquake and volcano.
The disposal of roadbed and slope is a weakness in freeway construction for a long time. In the metaphase of 1980's, our highway construction mostly give priority to low grade road. For the low traffic and small investment, deep digging and high filling are infrequent. So slope retaining engineering is not the principal engineering in highway construction and even be neglected. With the rapid development of highway construction, slope stability problem stands out increasingly in recent three decades. But being short of slope retaining research by the numbers, there are a lot of hidden dangers in highway construction. Once slopes lose their stability, the landslide will interrupt the traffic and even result in huge economic loss and bring on bad social influences. At the same time, it will greatly increase the evening slope retaining expense. Therefore, how to reinforce slopes efficiently and try our best to reduce the engineering cost for a practical slope when we select retaining project is very important.
In an other word, optimum design for slope retaining project is a principal considered problem.
This paper expatiates the design principle and apply condition of all kinds of slope retaining technology; summarizes slope class and the methods how to select slope reinforcement project; indicates the key factor of anchoring angle through the analysis of the anchoring mechanism, deduce the formula for the optimum and the maximum slide resistant anchoring angles respectively; analyze slope stability by finite element method and calculate stress, displacement, plastic zone through
c- reduction algorithm.
Furthermore, in combination with a practical slope engineering which lies in one freeway in Yunnan province, this paper use the upper theory and methods to carry out the optimum design for slope reinforcement project for a practical slope which lies the right side of K47+475-K47+630, and try to make this engineering safe, feasible and economical.
引文
[1] 黄求顺,张四平,胡岱文,边坡工程.重庆:重庆大学出版社,2003
[2] 陈祖煜,土质边坡稳定分析—原理·方法·程序.北京:中国水利水电出版社,2003
[3] 周伟义,彭衡和等.高速公路路堑边坡治理综合决策,公路,2003(1):113-117
[4] 杨宇航,颜志平,朱赞凌,罗志聪,公路边坡防护与治理.北京:人民交通出版社,2002
[5] 邵全,韦敏才,土力学与基础工程.重庆:重庆大学出版社,1997
[6] 周德培,张俊云,植被护坡工程技术.北京:人民交通出版社,2003
[7] 孙涛,顾波.边坡稳定性分析方法评述,岩土工程界,200l,5(11):48-50
[8] Bishop, A. W. The use of the slip circle in the stability analysis of slopes. Geotechnique, 1955, 1(1):7-17
[9] Chen, Zuyu and Morgenstern, N. R. Extensions to the generalized method of slices for stability analysis. Canadian Geotechnical Journal, 1983, 20(1): 104-119
[10] 钱家欢,殷宗泽,土工原理与计算.北京:中国水利水电出版社,1995
[11] HutChinson TN, Sarma S K. Discussion on three—dimensional limited equilibrium analysis of slope, Geotechnique, 1985, 35: 215-216
[12] Hungr O. An extension of Bishop's simplified method of slope stability analysis to three—dimensions, Geotechnique, 1987, 37:113-117
[13] 欧阳仲春.土坡稳定的塑性极限分析解,重庆交通学院学报,1983(3)
[14] 夏元友,李梅.边坡稳定性评价方法研究及发展趋势,岩石力学与工程学报,2002,21(7):1087-1091
[15] 魏永幸.滑坡防治工程技术现状及其展望,路基工程,2001(5):17-19
[16] 翟才旺.水利水电岩质边坡的加固技术综述,广西水利水电,2002(3):1-4
[17] 冯光乐,凌天清等.公路边坡支护方案优化设计,交通运输工程学报,2002,2(1):43-47
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[21] 孔宪宾,任青文.土钉墙技术及其发展,水利水电科技进展,2000,20(2):24-27
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[24] 李子军,徐清文,黄克胜,曾宪星.土钉支护及其应用,山东冶金,2001,23(4):29-32
[25] 赵志缙,应惠清,简明深基坑工程设计施工手册.北京:中国建筑工业出版社,2000
[26] 锚杆喷射混凝土支护技术规范(GB50086—2001).北京:中国计划出版社,2001
[27] 彭振斌,锚固工程设计计算与施工.武汉:中国地质大学出版社,1997
[28] 岩土工程勘察规范(GB50021-94).北京:中国建筑工业出版社,1994
[29] 建筑地基基础设计规范(GB50007—2002).北京:中国建筑工业出版社,2002
[30] 王晋明.岩土锚固技术在边坡整治中的应用,林业建设,2001(1):35-36
[31] 池淑兰、孔书祥、梁明学,路基及支挡结构.北京:中国铁道出版社,2001
[32] 刘光代.浅谈抗滑桩的设计,滑坡文集(第十五集),北京:中国铁道出版社,2002
[33] 佴磊,马丽英,冷曦晨,于清杨.滑坡治理中的抗滑桩设计,吉林大学学报,2002,32(2):162-164
[34] Ito, T., Matsui, T. Methods to estimate lateral force acting on stabilising piles. Soils and Foundations, 1975, 18(4): 43-49
[35] Poulos, H.G., Design of reinforcing piles to increase slope stability. Can. Geot. Jnl. 1995, 32:808-818
[36] Chen, L. T. and Poulos, H.G.. & Hull, T. S. Model tests on piles groups subjected to lateral soil movement, stability. Soils and Foundations, 1997,37(1): 1-12
[37] Guerpillion, Y., Boutonnier, L., G.ay, O., Foray, P. & Flavigny, E. Modelisation phisysique et numerique del's interaction d'un obstacle et d'un glessement d' epaisseur limitee.Proc. 12th Eur. Conf. Soil Mechs. Foundn. Eng. Amsterdam. 1999
[38] 交通部第二公路勘测设计院,公路设计手册·路基(第二版).北京:人民交通出版社,1996
[39] 铁道部第一勘测设计院,铁路工程设计技术手册·路基.北京:中国铁道出版社,1992
[40] 赵明阶,何光春,王多根,边坡工程处治技术.北京:人民交通出版社,2003
[41] 陈忠达,公路挡土墙设计.北京:人民交通出版社,2000
[42] 许兴杰,卫广恒,马淑萍,马兆龙.浅谈挡土墙设计,建筑技术,2003(4):32-33
[43] 李峻利,姚代禄,路基设计原理与计算.北京:人民交通出版社,2001
[43] 顾慰慈,挡土墙土压力计算.北京:中国建材工业出版社,2001
[44] 张远明,李梦华.边坡加固处治新技术的研究与应用,四川地质学报,2000,20(4):281-286
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土锚固新技术与西部开发.北京:人民交通出版社,2002
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[52] 喻林青.预应力锚索框架在土质边坡加固工程中的应用,路基工程,2001,(2):58-61
[53] 章青,朱虹,卓家寿.支护方案对岩石边坡稳定性的影响分析,河海大学学报,2001,29(12):27-30
[54] 肖世国,周德培.岩石高边坡的动态设计施工模式,岩石力学与工程学报,2002,21(9):1372-1374
[2] 陈祖煜,土质边坡稳定分析—原理·方法·程序.北京:中国水利水电出版社,2003
[3] 周伟义,彭衡和等.高速公路路堑边坡治理综合决策,公路,2003(1):113-117
[4] 杨宇航,颜志平,朱赞凌,罗志聪,公路边坡防护与治理.北京:人民交通出版社,2002
[5] 邵全,韦敏才,土力学与基础工程.重庆:重庆大学出版社,1997
[6] 周德培,张俊云,植被护坡工程技术.北京:人民交通出版社,2003
[7] 孙涛,顾波.边坡稳定性分析方法评述,岩土工程界,200l,5(11):48-50
[8] Bishop, A. W. The use of the slip circle in the stability analysis of slopes. Geotechnique, 1955, 1(1):7-17
[9] Chen, Zuyu and Morgenstern, N. R. Extensions to the generalized method of slices for stability analysis. Canadian Geotechnical Journal, 1983, 20(1): 104-119
[10] 钱家欢,殷宗泽,土工原理与计算.北京:中国水利水电出版社,1995
[11] HutChinson TN, Sarma S K. Discussion on three—dimensional limited equilibrium analysis of slope, Geotechnique, 1985, 35: 215-216
[12] Hungr O. An extension of Bishop's simplified method of slope stability analysis to three—dimensions, Geotechnique, 1987, 37:113-117
[13] 欧阳仲春.土坡稳定的塑性极限分析解,重庆交通学院学报,1983(3)
[14] 夏元友,李梅.边坡稳定性评价方法研究及发展趋势,岩石力学与工程学报,2002,21(7):1087-1091
[15] 魏永幸.滑坡防治工程技术现状及其展望,路基工程,2001(5):17-19
[16] 翟才旺.水利水电岩质边坡的加固技术综述,广西水利水电,2002(3):1-4
[17] 冯光乐,凌天清等.公路边坡支护方案优化设计,交通运输工程学报,2002,2(1):43-47
[18] 程良奎,范景伦,韩军,许建平,岩土锚固.北京:中国建筑工业出版社,2003
[19] 文华.建筑基坑土钉支护设计方法及计算机辅助设计:[学士学位论文].昆明:昆明理工大学建筑工程学院土木系,2001
[20] 钱勇,蒋胜波.土钉支护技术在公路工程中的应用,湖南交通科技,2002,28(3):23-25
[21] 孔宪宾,任青文.土钉墙技术及其发展,水利水电科技进展,2000,20(2):24-27
[22] 陈肇元,崔京浩,土钉支护在基坑工程中的应用.北京:中国建筑工业出版社,1997
[23] Mitchell, J. K. And Christopher, B. R. North America practice in reinforced Soil System. Design and Performance of Earth Retaining Structures, Proc. Of Conf. Cornel University, Ithaca, New York, June 1, ASCE, Geotechnical Special Publication, No.25. 1990, 322-345
[24] 李子军,徐清文,黄克胜,曾宪星.土钉支护及其应用,山东冶金,2001,23(4):29-32
[25] 赵志缙,应惠清,简明深基坑工程设计施工手册.北京:中国建筑工业出版社,2000
[26] 锚杆喷射混凝土支护技术规范(GB50086—2001).北京:中国计划出版社,2001
[27] 彭振斌,锚固工程设计计算与施工.武汉:中国地质大学出版社,1997
[28] 岩土工程勘察规范(GB50021-94).北京:中国建筑工业出版社,1994
[29] 建筑地基基础设计规范(GB50007—2002).北京:中国建筑工业出版社,2002
[30] 王晋明.岩土锚固技术在边坡整治中的应用,林业建设,2001(1):35-36
[31] 池淑兰、孔书祥、梁明学,路基及支挡结构.北京:中国铁道出版社,2001
[32] 刘光代.浅谈抗滑桩的设计,滑坡文集(第十五集),北京:中国铁道出版社,2002
[33] 佴磊,马丽英,冷曦晨,于清杨.滑坡治理中的抗滑桩设计,吉林大学学报,2002,32(2):162-164
[34] Ito, T., Matsui, T. Methods to estimate lateral force acting on stabilising piles. Soils and Foundations, 1975, 18(4): 43-49
[35] Poulos, H.G., Design of reinforcing piles to increase slope stability. Can. Geot. Jnl. 1995, 32:808-818
[36] Chen, L. T. and Poulos, H.G.. & Hull, T. S. Model tests on piles groups subjected to lateral soil movement, stability. Soils and Foundations, 1997,37(1): 1-12
[37] Guerpillion, Y., Boutonnier, L., G.ay, O., Foray, P. & Flavigny, E. Modelisation phisysique et numerique del's interaction d'un obstacle et d'un glessement d' epaisseur limitee.Proc. 12th Eur. Conf. Soil Mechs. Foundn. Eng. Amsterdam. 1999
[38] 交通部第二公路勘测设计院,公路设计手册·路基(第二版).北京:人民交通出版社,1996
[39] 铁道部第一勘测设计院,铁路工程设计技术手册·路基.北京:中国铁道出版社,1992
[40] 赵明阶,何光春,王多根,边坡工程处治技术.北京:人民交通出版社,2003
[41] 陈忠达,公路挡土墙设计.北京:人民交通出版社,2000
[42] 许兴杰,卫广恒,马淑萍,马兆龙.浅谈挡土墙设计,建筑技术,2003(4):32-33
[43] 李峻利,姚代禄,路基设计原理与计算.北京:人民交通出版社,2001
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