不同工况下矿区边坡受力变形及破坏特征研究

doi:10.16265/j.cnki.issn1003-3033.2025.S2.0022

摘要/Abstract

摘要：

为提高矿区安全开采与灾害防控,以江西某锂矿矿区1号排土场为研究对象,通过现场调查、岩土力学试验及三维数值模拟方法,系统分析排土场的受力变形特征与失稳机制。基于薄片鉴定与岩体质量分级,明确全风化、强风化及中风化花岗岩的物理力学参数差异,综合选取Hoek-Brown准则、费辛柯法、格吉法和工程规范法折减计算岩体力学参数,结合工程地质类比法,确定填土、碎石、不同风化程度花岗岩的力学参数,采用FLAC3D软件构建三维数值模型,模拟自重+地下水、爆破振动及强降雨3种工况下的边坡响应。结果表明:自重工况下边坡安全系数为1.46,位移集中于5-5'剖面坡底(最大沉降9.5 mm);爆破振动使安全系数降至1.41,位移增至124.7 mm;强降雨(日降雨量300 mm)导致安全系数进一步降至1.398,最大位移达166.2 mm。揭示爆破与降雨是影响稳定性的关键因素,在施工中加强坡底监测并优化防护措施。

关键词: 受力变形, 破坏特征, 边坡稳定性, 数值模拟, 排土场

Abstract:

To enhance safe mining and disaster prevention and control in mining areas, the No. 1 waste dump in a lithium mine in Jiangxi Province was studied, and the stress-deformation characteristics and instability mechanism of the waste dump were systematically analyzed through field investigations, geotechnical mechanics experiments, and three-dimensional numerical simulation methods. Based on thin-section identification and rock mass quality classification, the differences in the physical and mechanical parameters of fully weathered, strongly weathered, and moderately weathered granite were clarified. The Hoek-Brown criterion, the Feschenko method, the Geji method, and the engineering specification method were comprehensively selected to reduce and calculate the mechanical parameters of the rock mass. Combined with the engineering geological analogy method, the mechanical parameters of fill soil, gravel, and granite with different weathering degrees were determined. The FLAC3D software was used to construct a three-dimensional numerical model to simulate the slope responses under three working conditions: self-weight and groundwater, blasting vibration, and heavy rainfall. The results show that: under the self-weight condition, the safety factor of the slope is 1.46, and the displacement is concentrated at the bottom of the 5-5' section slope, where the maximum settlement reached 9.5 mm. The blasting vibration reduces the safety factor to 1.41, and the displacement increases to 124.7 mm; heavy rainfall with a daily precipitation of 300 mm further reduces the safety factor to 1.398, and the maximum displacement reaches 166.2 mm. The research reveals that blasting and rainfall are the key factors affecting the stability. It is recommended to strengthen the monitoring at the slope bottom and optimize the protection measures during construction.

Key words: force deformation, destructive feature, slope stability, numerical simulation, waste dump

中图分类号:

X948

温经林, 尹永明, 于正兴, 王一帆, 卢新爱. 不同工况下矿区边坡受力变形及破坏特征研究[J]. 中国安全科学学报, 2025, 35(S2): 66-72.

WEN Jinglin, YIN Yongming, YU Zhengxing, WANG Yifan, LU Xin'ai. Force deformation and destructive features of mine slopes under varied conditions[J]. China Safety Science Journal, 2025, 35(S2): 66-72.

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试验项目	全风化花岗岩	强风化花岗岩	中风化花岗岩
含水率ω/%	16.76	0.50	0.51
饱和密度/(g·cm^-3)	1.92	2.50	2.60
干密度/(g·cm^-3)	1.65	2.48	2.59
饱和含水率ω_sa/%	23.22	0.55	0.59
点荷载	0.03	0.62	0.83
单轴抗压强度/MPa	/	21.15	55.95
内摩擦角/(°)	24.6	31.56	32.22
黏聚力/MPa	0.017 4	5.64	15.61
弹性模量E₅₀/GPa	0.07	7.18	9.98

岩石类型	坚固性系数	RQD质量分级	RMR岩体质量分级	综合评价
强风化花岗岩	Ⅳ	Ⅴ	Ⅳ	Ⅴ
中风化花岗岩	Ⅳa	Ⅳ	Ⅲ	Ⅳ

剖面要素		中风化花岗岩
剖面	高度/m	黏聚力/kPa	内摩擦角/(°)
1-1'	41	455.43	40
2-2'	69	429.35	40.37
3-3'	119	405.06	36.2
4-4'	168	391.07	33.57
5-5'	230	379.13	31.2
6-6'	75	425.45	39.73

岩层	黏聚力/ kPa	内摩擦角/ (°)	重度/ (kN·m^-3)
填土	14.30	24	17.5
碎石	34	25	20
全风化花岗岩	17.4	24.60	16.50
强风化花岗岩	100.00	26.30	25

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