采空区路堤边坡滑塌的风险评估模型

doi:10.16265/j.cnki.issn1003-3033.2026.02.0206

摘要/Abstract

摘要：

为解决采空区路堤边坡滑塌风险评估中存在的不确定性与多态故障难以准确描述的问题,提出一种基于改进T-S模糊故障树的采空区路堤边坡滑塌风险评估模型。首先,引入高斯模糊数表征各基本事件的故障状态和发生概率,以处理传统故障分析中对数据精确概率的过度依赖,以及事件中间状态表达不足的局限;然后,采用T-S模糊模型替代传统逻辑门中的“与”“或”关系,刻画事件间的不确定性和模糊信息特征,进而推导出边坡发生滑塌的故障概率;最后,通过工程实例进行验证。结果表明:该方法能降低故障树的建立难度,能够识别边坡滑塌的关键致险因子,并给出其影响程度排序,反映出滑塌事件与各因素间的内在关联。

关键词: 采空区, 路堤边坡, 滑塌, T-S模糊故障树, 高斯模糊数, 风险评估

Abstract:

To address the challenges in accurately describing uncertainty and multiple failure modes in the risk assessment of embankment slope failures in goaf areas, a risk assessment model based on an improved T-S fuzzy fault tree approach was proposed. Initially, Gaussian fuzzy numbers were introduced to characterize the failure states and occurrence probabilities of basic events, thereby addressing the over-reliance on precise probabilistic data in conventional fault tree analysis and the insufficient representation of intermediate event states. Subsequently, T-S fuzzy model was employed to replace traditional AND/OR relationships in logic gates, capturing the uncertainty and fuzzy characteristics among events, and thereby deriving the failure probability of slope collapse. Finally, an engineering case study was conducted for validation. The results demonstrate that the proposed approach simplifies the fault tree construction, identifies the key risk factors leading to slope failure, provides a ranking of their influence, and reveal the intrinsic relationships between failure events and various factors.

Key words: mining goafs, embankment slopes, collapse, Takagi-Sugeno (T-S) fuzzy fault tree, gaussian fuzzy number, risk assessment

中图分类号:

X936

赵博. 采空区路堤边坡滑塌的风险评估模型[J]. 中国安全科学学报, 2026, 36(2): 121-126.

ZHAO Bo. Risk assessment model for embankment slope failure in mining goafs[J]. China Safety Science Journal, 2026, 36(2): 121-126.

图/表 6

图1

图2

图3

表1

表2

表3

对采空区路堤边坡滑塌影响较大的基本事件的T-S概率重要度

序号	重要基本事件	$I T p = 0.5 P r (x' i)$	重要基本事件	$I T p = 1.0 P r (x' i)$
1	不利岩土体x₃	0.042 5	地应力高x₁	0.010 2
2	采空区浅埋x₈	0.029 5	陡峭地形x₇	0.006 8
3	地表水下渗x₁₁	0.050 1	地震x₁₅	0.010 9
4	降雨x₂₀	0.037 8	爆破x₂₅	0.008 5
5	矿山开采x₂₂	0.057 6	采空区处理x₂₉	0.012 1
6	监控预警不及时x₃₅	0.061 5	加固支护x₃₇	0.007 8

表3

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