Water abundance assessment model development and water hazard control strategies for karst aquifers in metal mines: A case study of the Maoping lead zinc mine in Northeast Yunnan, China
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摘要:
针对岩溶区金属矿山仅依据钻孔单位涌水量划分岩溶含水层富水性的缺陷,以滇东北典型深采矿山毛坪铅锌矿为例,在充分考虑其水文地质结构特征的基础上,从渗流场特征、含水层特征、构造发育特征3方面,构建了包含渗透系数、水位降深、单位涌水量、含水层有效厚度、水样溶解性总固体、断层发育密度、冲洗液消耗量等7个评价指标的层次结构评价模型。采用层次分析法计算得到了各评价指标的主观权重,并在ArcGIS系统内根据富水性指数将研究区划分为弱富水区,较弱富水区,中等富水区,较强富水区,强富水区5个区域。评价结果表明:毛坪铅锌矿石门坎背斜西翼岩溶含水层的富水性整体较强;石门坎背斜轴部岩溶含水层的富水性呈现出上强下弱的特点;石门坎背斜东翼岩溶含水层的富水性总体偏弱,且浅部岩溶含水层的富水性向东逐渐减弱。针对金属矿山采掘揭露局部强富水区诱发高势能突水灾害,提出了“骨料灌注→充填注浆→水源封堵”的被动治理方式;以及针对区域强富水含水层的“物探先行→钻探验证→区域超前帷幕注浆”的主动治理方式。研究结果对于指导金属矿山深部采掘空间布置和制订疏放水方案具有重要的参考意义。
Abstract:To address the limitations of relying solely on borehole-specific water inflow rates to evaluate the water abundance of karst aquifers in metal mines, this study presented a comprehensive assessment in the Maoping lead zinc mine in Northeastern Yunnan, a typical deep karst mining area, using a hierarchical evaluation model for karst aquifer water abundance. This model integrated three key dimensions: Seepage field characteristics (permeability coefficient, water level drawdown, and unit water inflow), aquifer characteristics (effective thickness of aquifer and total dissolved solids in water samples), and structural development characteristics (fault density and drilling fluid loss). Subjective weights for each evaluation indicator were determined using the analytic hierarchy process (AHP). Using ArcGIS platform, the study area was categorized into five distinct water-richness zones based on the water abundance index thresholds: very low water-rich area, low water-rich area, moderate water-rich area, high water-rich area, and very high water-rich area. The evaluation results demonstrate that the karst aquifer in the western wing of the Shimenkan anticline, located at the Maoping lead zinc mine in Northeastern Yunnan, exhibits high overall water abundance. The karst aquifer in the axial zone of the Shimenkan anticline exhibits significant vertical zonation in water abundance, characterized by high values in the upper strata and low values in the lower strata. The water abundance of the karst aquifer in the eastern wing of the Shimenkan anticline is generally weak, and the water abundance of the shallow karst aquifer gradually weakens towards the east. The passive governance mode of “aggregate injection→filling grouting→water source blockage” was used to address the high potential water inrush disasters induced by the exposure of local strong water-rich areas in metal mines; the active governance mode of “geophysical exploration first→drilling verification→regional advanced curtain grouting” for strong water-rich aquifers in the region. This study offers critical technical guidance for optimizing deep mine layout and developing effective drainage strategies in karst metal mining regions.
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表 1 9级标度打分表
Table 1. Scale rating of nine grades
序号 重要性等级级别 Cij标度值 1 指标i比指标j同等重要 1 2 指标i比指标j稍微重要 3 3 指标i比指标j明显重要 5 4 指标i比指标j强烈重要 7 5 指标i比指标j极端重要 9 6 指标i比指标j稍不重要 1/3 7 指标i比指标j明显不重要 1/5 8 指标i比指标j强烈不重要 1/7 9 指标i比指标j极端不重要 1/9 
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表 2 A-Bi (i=1, 2, 3)判断矩阵
Table 2. Judgment matrix of A-Bi (i=1, 2, 3)
A B1 B2 B3 B1 1 4 5 B2 1/4 1 5 B3 1/5 1/2 1
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表 3 B1-Ci (i=1, 2, 3)判断矩阵
Table 3. Judgment matrix of B1-Ci (i=1, 2, 3)
B1 C1 C2 C3 C1 1 3 1/2 C2 1/3 1 1/4 C3 2 4 1
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表 6 基于AHP的权重计算结果
Table 6. Weight calculation results based on AHP method
目标层 准则层 权重
Bi (i=1~3)指标层 指标权重
Ci (i=1~7)金属矿山
岩溶含水层
富水性
评价(A)渗流场特征
(B1)0.6833 渗透系数(C1) 0.2184 水位降深(C2) 0.0833 单位涌水量(C3) 0.3816 含水层特征
(B2)0.1999 含水层有效厚度(C4) 0.1499 水样溶解性总固体(C5) 0.0500 构造发育
特征(B3)0.1168 断层发育密度(C6) 0.0779 冲洗液消耗量(C7) 0.0389
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