复杂堆积层边坡开挖变形机理及加固效果评价
摘要:针对某电力工程换流站高挖方边坡,分别采用极限平衡法和强度折减法对边坡的稳定性和变形特征进行分析。分析结果表明,边坡的稳定性受降雨和地震作用影响显著,两种工况下边坡均处于不稳定状态,地震作用对斜坡地带堆积体结构形成损伤,不但使边坡整体稳定性下降,还促使坡体内裂隙大量发育,利于降雨入渗,进一步恶化边坡的水文地质条件,导致坡体孔隙水压力增加、有效应力降低。边坡加固设计采用桩板墙+坡面格构锚杆支护措施,加固后边坡稳定性系数达到1.406,最大总位移由加固前的425 mm降至9 mm,大幅提高边坡稳定性,表明防护方案能保障边坡安全性,达到防治和风险管控的目的。
Abstract:For a high excavation slope of a converter station in a power engineering project, the stability and deformation characteristics of the slope were analyzed using the limit equilibrium method and the strength reduction method, respectively. The results showed that the stability of the slope is significantly affected by rainfall and earthquakes. The slope was in an unstable state under both working conditions. Earthquake induced damage to the accumulation structure of slope zones. Not only does it reduce the overall stability of the slope, but it also promotes the extensive development of cracks within the slope. It was beneficial for rainfall infiltration and further deteriorating the hydrogeological conditions of the slope, and it caused an increase in pore water pressure and a decrease in effective stress in the slope. The slope reinforcement design adopted the support measures of pile sheet wall and lattice anchor rod. The stability coefficient of the reinforced slope reached 1.406, and the maximum total displacement decreased from 425 mm before reinforcement to 9 mm. It significantly improved slope stability and indicated that the protection plan can ensure the safety of the slope and achieve the purpose of prevention and risk control.
中文标题:
复杂堆积层边坡开挖变形机理及加固效果评价
Deformation Mechanism and Reinforcement Effect for Slope Excavated in Complex Accumulative Formation
作者:
涂新斌1,,王彦兵1,杨相斌2,,牛彦博2,袁明生2,高献3,林少远4,陈熙隆3
Tu Xinbin1,,Wang Yanbing1,Yang Xiangbin2,,Niu Yanbo2,Yuan Mingsheng2,Gao Xian3,Lin Shaoyuan4,Chen Xilong3
作者简介:涂新斌,男,1971年生,汉族,湖北孝感人,博士,正高级工程师,从事岩土工程与地质工程研究。E-mail:tuxinbin11891@qq.com
通讯地址:
1.国网经济技术研究院有限公司,北京 102209 2.中国电力工程顾问集团西南电力设计院有限公司,四川成都 610021 3.国网福建省电力有限公司经济技术研究院,福建福州 350011 4.国网福建省电力有限公司,福建福州 350003
1.StateGridEconomicandTechnologicalResearchInstituteCo.,Ltd.,Beijing102209,China 2.SouthwestElectricPowerDesignInstituteCo.,Ltd.ofCPECC,Chengdu610021,Sichuan,China 3.EconomicandTechnologicalResearchInstitute,StateGridFujianElectricPowerCompany,Fuzhou,350011,FuJian,China 4.StateGridFujianElectricPowerCompany,Fuzhou350003,FuJian,China
中图分类号:P642
doi:10.3969/j.issn.1007-2993.2024.02.008
出版物:岩土工程技术
收稿日期:2023-02-10
修回日期:2023-06-12
录用日期:2023-11-08
刊出日期:2024-04-11
关键词:堆积体滑坡,高挖方边坡,边坡稳定性,强度折减法,数值模拟
Key words:accumulation landslide,high excavation slope,slope stability,strength reduction method,numerical simulation
文档包含图片数量:图片(12)张
文档包含表格数量:表格(4)个
参考文献:
[1]胡正涛. 锚杆挡墙与锚喷结构在挖方边坡支护中的应用[J]. 河南科技,2021,40(27):66-68. doi: 10.3969/j.issn.1003-5168.2021.27.024
[2]徐 伟,华锡昌. 论环境边坡工程的设计与防治措施[J]. 资源环境与工程,2009,23(4):432-435. doi: 10.3969/j.issn.1671-1211.2009.04.014
[3]刘海亭,张小辉,朱有禄,等. 高边坡稳定性评价、加固措施和监测分析[J]. 岩土工程技术,2020,34(2):76-80. doi: 10.3969/j.issn.1007-2993.2020.02.003
[4]吴祖成,郭山峰,何伟民. 矿山高陡岩质边坡治理应用研究[J]. 岩土工程技术,2021,35(1):48-51.
[5]覃 胸,吴俊良. 采用Midas GTS NX软件进行中风化岩层垂直边坡开挖支护稳定性分析[J]. 西部交通科技,2022,(2):66-72.
[6]王佳男,孙叶俊,姚 露. 边坡支护技术在土木工程中的应用[J]. 散装水泥,2021,(5):81-83. doi: 10.3969/j.issn.1007-3922.2021.05.028
[7]杨逸飞,孙少锐,闵 望,等. 顺层岩质边坡稳定性分析及加固设计研究[J]. 岩土工程技术,2023,37(1):66-71.
[8]覃 怡,颜 志. 岩质边坡稳定性分析及加固设计研究[J]. 黑龙江交通科技,2018,41(8):58-59. doi: 10.3969/j.issn.1008-3383.2018.08.036
[9]冉 涛,陈 浩,王羽珂,等. 工程开挖活动诱发堆积层滑坡变形机理及加固效果分析[J]. 地质与勘探,2022,58(6):1236-1251. doi: 10.12134/j.dzykt.2022.06.008
[10]张秋霞,文丽娜,朱崇林,等. 某堆积体滑坡成因机理及稳定性分析[J]. 地质灾害与环境保护,2022,33(3):3-9. doi: 10.3969/j.issn.1006-4362.2022.03.001
[11]胡爱国,周 伟. 地震与强降雨作用下堆积体滑坡变形破坏机理及防治方案分析[J]. 中国地质灾害与防治学报,2022,33(1):27-34.
基金项目:
基金项目:国家电网有限公司总部管理科技项目(5200-202156074A-0-0-00)
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