| 颗粒离散元分层建模法及颗粒尺寸效应 |
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| 引用本文: | 陈龙,吴顺川,金爱兵.颗粒离散元分层建模法及颗粒尺寸效应[J].西南交通大学学报,2022,57(5):1086-1095. |
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| 作者姓名: | 陈龙 吴顺川 金爱兵 |
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| 作者单位: | 1.北京科技大学金属矿山高效开采与安全教育部重点实验室,北京 1000832.昆明理工大学国土资源工程学院,云南 昆明 650093 |
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| 基金项目: | 国家自然科学基金(51774020,51934003) |
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| 摘 要: | 离散元分析方法是研究岩石力学行为、完善岩石力学基础理论的重要工具之一,为提高颗粒离散元法模拟室内岩石力学及大规模工程尺度试验的精确度,提出分层建模法,该方法对岩石或岩体关注区域采用小尺寸颗粒进行精细化模拟,外侧非重点关注区域采用大尺寸颗粒建模以扩大计算区域. 采用分层建模法进行单轴压缩、巴西劈裂试验并与常规建模计算结果进行对比,初步验证了分层建模法模拟室内力学试验的可行性. 研究结果表明:分层建模法与常规建模一样受颗粒尺寸效应影响,但可以减少颗粒流模型中的颗粒数量,计算效率提高50%以上;分层模型的单轴抗压强度和起裂应力分别与外层对应的常规模型相比,最多仅减小2.7%和1.9%,匹配单轴抗压强度时可先以外层材料常规模型作参照,单轴抗压强度和起裂应力的变异系数(coefficient of variation,COV)普遍大于常规模型,但依然在2%的可接受范围内;分层模型中粒径分布的不均匀性对模型弹性阶段的变形性质影响较小,分层模型的弹性模量与外层对应的常规模型相比减小1.3% ~ 2.3%;分层模型的巴西劈裂抗拉强度与外层对应的常规模型增大了1.32% ~ 2.35%,宏观破裂特征与小粒径常规模型相似,但在加载板附近有更多的裂纹.
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| 关 键 词: | 分层建模法 离散元 颗粒尺寸 三维建模 |
| 收稿时间: | 2021-01-11 |
Particle Discrete Element Layered Modeling Method and Particle Size Effect |
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| CHEN Long,WU Shunchuan,JIN Aibing.Particle Discrete Element Layered Modeling Method and Particle Size Effect[J].Journal of Southwest Jiaotong University,2022,57(5):1086-1095. |
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| Authors: | CHEN Long WU Shunchuan JIN Aibing |
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| Affiliation: | 1.Key Laboratory of Ministry of Education for Efficient Mining and Safety of Metal Mine, University of Science and Technology Beijing, Beijing 100083, China2.Faculty of Land Resources Engineering, Kunming University of Science and Technology, Kunming 650093, China |
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| Abstract: | Discrete element analysis method is one of the important tools for studying rock mechanics behavior and refining the basic theory of rock mechanics. In order to improve the accuracy of the particle discrete element method to simulate indoor rock mechanics and large-scale engineering scale tests, a layered modeling method is proposed. This method adopts small-size particles for fine simulation of the rock or key rock mass area, and large-size particles for the outside area to expand the calculation area. The layered modeling method is used to carry out uniaxial compression and Brazilian splitting tests, and compared with the conventional modeling calculation results, which preliminarily verifies its feasibility to simulate indoor mechanical tests. The results show that the layered modeling method is affected by the particle size like conventional modeling, but it can reduce the number of particles in the particle flow code model and increase the calculation efficiency by more than 50%. The uniaxial compressive strength and crack initiation stress of the layered model are reduced by only 2.7% and 1.9% at most, compared with those of the conventional model with the corresponding outer layer. The coefficient of variation (COV) of uniaxial compressive strength and crack initiation stress is generally larger than that of the conventional model, but it is still within the acceptable range of 2%. The inhomogeneity of particle size distribution in the layered model has minor effect on the deformation properties of the model at the elastic stage, and the elastic modulus of the layered model is reduced by 1.3%?2.3% compared with the conventional model with the corresponding outer layer. The overall Brazilian splitting tensile strength of the layered model is increased by 1.32%?2.35% compared to that of the conventional model with the corresponding outer layer, and the macroscopic fracture characteristics are similar to those of the conventional small-particle model, but there are more cracks near the loading plate. |
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