| 反倾层状岩质边坡倾倒变形机理与影响因素的离散元模拟 |
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| 引用本文: | 黄达,马昊,石林.反倾层状岩质边坡倾倒变形机理与影响因素的离散元模拟[J].吉林大学学报(地球科学版),2021,51(6):1770-1782. |
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| 作者姓名: | 黄达 马昊 石林 |
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| 作者单位: | 1. 河北工业大学土木与交通学院, 天津 300401;2. 重庆大学土木工程学院, 重庆 400044;3. 长安大学地质工程与测绘学院, 西安 710054;4. 中铁第四勘察设计院集团有限公司, 武汉 430063 |
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| 基金项目: | 国家自然科学基金项目(41672300,41972297) |
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| 摘 要: | 为进一步研究层状反倾边坡的弯曲倾倒变形机制,以离心试验为原型,通过离散元数值模拟,研究了层状岩质反倾边坡的变形机理与影响因素。通过预置层内随机裂隙,实现了破裂面的形成和贯通。研究结果表明:模拟结果与试验吻合较好,边坡变形可分为起始蠕变、稳态变形和失稳破坏3个阶段;边坡破裂面在达到破坏荷载(Gf)后瞬间贯通,呈直线型,产状受岩层倾角控制,Gf值与坡角幂函数相关;反倾边坡的破坏需满足倾角和坡角启动条件,且变形破坏与岩层所受弯矩关系密切,当倾角为70°~80°、坡角大于60°时,最易破坏;典型破坏模式有倾倒-折断-块体式、倾倒-弯曲-折断式、倾倒-反折式3种,其受倾角、坡角组合控制;对材料参数的正交试验表明,各参数对Gf的敏感性从大到小依次为密度、层面内摩擦角、层厚、密度比、层面黏聚力,且Gf与层厚、层面内摩擦角及密度比具有良好的线性相关性;层面内摩擦角可影响破裂面产状,从而控制变形体规模,其他参数仅影响Gf的大小。
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| 关 键 词: | 离心模型试验 离散元 反倾边坡 倾倒变形 |
| 收稿时间: | 2020-02-10 |
Discrete Element Simulation of Toppling Mechanism and Influencing Factors of Anti-Dip Layered Rock Slope |
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| Huang Da,Ma Hao,Shi Lin.Discrete Element Simulation of Toppling Mechanism and Influencing Factors of Anti-Dip Layered Rock Slope[J].Journal of Jilin Unviersity:Earth Science Edition,2021,51(6):1770-1782. |
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| Authors: | Huang Da Ma Hao Shi Lin |
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| Affiliation: | 1. School of Civil and Transportation, Hebei University of Technology, Tianjin 300401, China;2. School of Civil Engineering, Chongqing University, Chongqing 400044, China;3. College of Geological Engineering and Geomatics, Chang'an University, Xi'an 710054, China;4. China Railway Siyuan Survey and Design Group Co., Ltd., Wuhan 430063, China |
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| Abstract: | In order to further study the mechanism and influcing factors of the toppling of layered anti-dip slopes, the discrete element simulation based on centrifugal model test was adopted. The formation of rupture surface was realized by presetting random cracks in the rock layers. The simulation results are in good agreement with the physical test. Slope deformation can be divided into three stages:Initial creep, steady-state deformation, and instability failure. The results show that:The rupture surface is straight-line after the failure load (Gf) is reached, and the occurrence is controlled by the dip angle of the rock layer; The Gf value is related to the power function of the slope angle; The failure of the anaclinal slope needs to satisfy the initial conditions, and the deformation is closely related to the bending moment of the rock layer, when the dip angle is 70°-80° and the slope angle is larger than 60°, it is the most vulnerable state. There are three typical failure modes:Toppling-rupture-block detachment type, toppling-bend-rupture type, and toppling-reversal type, which are controlled by the combination of dip and slope angle. The orthogonal simulations on material parameters show that the sensitivity of each parameter to Gf from large to small is density, friction angle of beddings, layer thickness, density ratio, and cohesion of beddings; The value of friction angle of beddings can affect the occurrence of the rupture surface, thus controlling the size of the deformation area, while other parameters only affect the value of Gf. |
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| Keywords: | centrifugal model test discrete element method anaclinal slope toppling deformation |
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