院报 ›› 2024, Vol. 41 ›› Issue (6): 130-135.DOI: 10.11988/ckyyb.20230560

• 岩土工程 • 上一篇    下一篇

基于图表法的岩质斜坡永久位移快速计算方法

李丞1, 张永进1, 曾科1, 徐兴倩2, 屈新3   

  1. 1.凯里学院 建筑工程学院,贵州 凯里 556011;
    2.云南农业大学 水利学院,昆明 650201;
    3.安阳工学院 土木与建筑工程学院,河南 安阳 455000
  • 收稿日期:2023-05-22 修回日期:2023-11-01 出版日期:2024-06-01 发布日期:2024-06-03
  • 通讯作者: 屈 新(1987-),男,湖北麻城人,讲师,博士,研究方向为岩体变形破坏数值模拟。E-mail:xqu1987@163.com
  • 作者简介:李 丞(1990-),男,苗族,贵州麻江人,讲师,博士,研究方向为山地灾害防治。E-mail:licheng_730@163.com
  • 基金资助:
    贵州省教育厅高等学校科学研究项目(青年项目)(黔教技[2022]361);国家自然科学基金项目(42307269,42107195);凯里学院博士启动专项课题(BS20230101);黔东南州科技计划项目(黔东南科合J字([2022]51号));安阳市重点研发与推广科技攻关项目(2023C01SF211)

A Chart-based Method of Rapidly Calculating Permanent Displacement of Rock Slope

LI Cheng1, ZHANG Yong-jin1, ZENG Ke1, XU Xing-qian2, QU Xin3   

  1. 1. School of Architectural Engineering,Kaili University,Kaili 556011,China;
    2. School of Water Resources, Yunnan Agricultural University, Kunming 650201, China;
    3. School of Civil and Architecture Engineering, Anyang Institute of Technology, Anyang 455000, China
  • Received:2023-05-22 Revised:2023-11-01 Online:2024-06-01 Published:2024-06-03

摘要: 岩质斜坡地震稳定性的快速评价是学者们关注的热点和难点。传统上,大多数研究采用图表法得到的安全系数快速评价岩质斜坡的地震稳定性,目前缺乏快速计算岩质斜坡临界加速度的方法。如何构建临界加速度模型是计算斜坡永久位移的前提条件。为此,采用有限元极限分析方法(平均界解)和广义Hoek-Brown强度准则,提出了一种快速计算岩质斜坡临界加速度的新方法。对概化岩质斜坡进行数值建模,基于1 960次的案例计算结果,绘制了岩质斜坡临界加速度图,通过2次拟合统计分析,构建了岩质斜坡临界加速度与斜坡几何条件和强度参数的函数表达式,并将本文方法与Newmark模型和数值解进行了比较。结果表明,本文方法的计算精度比Newmark模型更接近数值解。所开发的岩质斜坡永久位移计算方法高效、便捷,不仅能够用于单体斜坡地震稳定性的快速计算,还可以为计算区域尺度内大量斜坡的永久位移提供技术支撑。

关键词: 岩质斜坡, 图表法, 有限元极限分析, 广义Hoek-Brown强度准则, 临界加速度, Newmark模型, 永久位移, 快速计算

Abstract: The rapid calculation of seismic stability of rock slopes remains a prominent and challenging focus among scholars. Historically, the chart method has been predominant in acquiring safety factors to swiftly evaluate the seismic stability of such slopes. However, approaches for promptly determining the critical acceleration of rock slopes are in lack. Establishing a model for critical acceleration is a prerequisite for computing the permanent displacement of slopes. To address this issue, we present a novel approach for swiftly computing the critical acceleration of rock slopes by employing the finite element limit analysis method (mean bound solution) and the generalized Hoek-Brown strength criterion. We obtained the diagram of critical acceleration based on 1 960 case calculations via numerical simulations for a generalized rock slope. Subsequent to two fitting statistical analyses, we derived a functional relationship between the critical acceleration of rock slopes and their geometric attributes and strength parameters. Comparisons of the results of the proposed method with those of the Newmark model and numerical solutions demonstrate that the computational accuracy of the proposed method aligns more closely with numerical solutions compared to the Newmark model. The developed method for calculating permanent displacement in rock slopes proves efficient and convenient. It not only facilitates the rapid assessment of seismic stability for individual slopes but also offers technical support for calculating permanent displacement across a large number of slopes on regional scale.

Key words: rock slope, stability charts, finite element limit analysis, generalized Hoek-Brown strength criterion, critical acceleration, Newmark model, permanent displacement, rapid calculation

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