Research on the prediction of mine water inrush disasters based on multi-factor spatial game reconstruction

IF 3.9 2区 工程技术 Q3 ENERGY & FUELS Geomechanics and Geophysics for Geo-Energy and Geo-Resources Pub Date : 2024-02-07 DOI:10.1007/s40948-024-00761-1
Qiushuang Zheng, Changfeng Wang, Zhenhao Zhu
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Abstract

Water damage in mines poses a widespread challenge in the coal mining industry. Gaining a comprehensive understanding of the multi-factor spatial catastrophe evolution mechanism and process of floor water inrush is crucial, which will enable the achievement of dynamic, quantitative, and precise early warning systems. It holds significant theoretical guidance for implementing effective water prevention and control measures in coal mines. This study focuses on the issue of water inrush in the coal seam floor, specifically in the context of Pengzhuang coal mine. By utilizing a small sample of non-linear characteristics derived from drilling geological data, we adopt a multifactor spatial perspective that considers geological structure and hydrogeological conditions. In light of this, we propose a quantitative risk prediction model that integrates the coupled theoretical analysis, statistical analysis, and machine learning simulation methods. Firstly, the utilization of a quantification approach employing a triangular fuzzy number allows for the representation of a comparative matrix based on empirical values. Simultaneously, the networked risk transmission effect of underlying control risk factors is taken into consideration. The application of principal component analysis optimizes the entropy weight method, effectively reducing the interference caused by multifactor correlation. By employing game theory, the subjective and objective weight proportions of the control factors are reasonably allocated, thereby establishing a vulnerability index model based on a comprehensive weighting of subjective and objective factors. Secondly, the WOA-RF-GIS approach is employed to comprehensively explore the interconnectedness of water diversion channel data. Collaborative Kriging interpolation is utilized to enhance the dimensionality of the data and facilitate spatial information processing. Lastly, the representation of risk is coupled with necessary and sufficient condition layers, enabling the qualitative visualization of quantitative results. This approach aims to accurately predict disaster risk with limited sample data, ultimately achieving the goal of precise risk assessment. The research findings demonstrate that the reconstructed optimization model based on multi-factor spatial game theory exhibits high precision and generalization capability. This model effectively unveils the non-linear dynamic processes associated with floor water inrush, which are influenced by multiple factors, characterized by limited data volume, and governed by complex formation mechanisms. The identification of high-risk areas for water inrush is achieved with remarkable accuracy, providing invaluable technical support for the formulation of targeted water prevention and control measures, ultimately ensuring the safety of coal mining operations.

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基于多因素空间博弈重构的矿井涌水灾害预测研究
矿井水害是煤矿行业面临的一个普遍挑战。全面了解底板涌水的多因素空间灾害演化机理和过程,对于建立动态、定量、精确的预警系统至关重要。它对煤矿实施有效的防治水措施具有重要的理论指导意义。本研究以彭庄煤矿为研究对象,重点探讨煤层底板涌水问题。通过利用钻探地质数据得出的非线性特征小样本,我们采用了多因素空间视角,考虑了地质结构和水文地质条件。在此基础上,我们提出了一个集理论分析、统计分析和机器学习模拟方法于一体的定量风险预测模型。首先,利用三角模糊数的量化方法,可以表示基于经验值的比较矩阵。同时,还考虑了潜在控制风险因素的网络风险传递效应。主成分分析法的应用优化了熵权法,有效减少了多因素相关性带来的干扰。运用博弈论,合理分配控制因素的主客观权重比例,从而建立了基于主客观因素综合权重的脆弱性指数模型。其次,采用 WOA-RF-GIS 方法全面探索引水渠道数据的相互关联性。利用协同克里金插值法提高数据维度,方便空间信息处理。最后,风险表征与必要条件层和充分条件层相结合,实现了定量结果的定性可视化。这种方法旨在利用有限的样本数据准确预测灾害风险,最终实现精确风险评估的目标。研究结果表明,基于多因素空间博弈论的重构优化模型具有较高的精度和泛化能力。该模型有效揭示了地面涌水的非线性动态过程,该过程受多种因素影响,数据量有限,形成机制复杂。该模型能够准确识别高风险涌水区域,为制定有针对性的防治水措施提供了宝贵的技术支持,最终确保煤矿安全生产。
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来源期刊
Geomechanics and Geophysics for Geo-Energy and Geo-Resources
Geomechanics and Geophysics for Geo-Energy and Geo-Resources Earth and Planetary Sciences-Geophysics
CiteScore
6.40
自引率
16.00%
发文量
163
期刊介绍: This journal offers original research, new developments, and case studies in geomechanics and geophysics, focused on energy and resources in Earth’s subsurface. Covers theory, experimental results, numerical methods, modeling, engineering, technology and more.
期刊最新文献
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