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我国煤矿区矿井水污染问题及防控技术体系构建

孙亚军 徐智敏 李鑫 张莉 陈歌 赵先鸣 高雅婷 刘琪 张尚国 汪韦峻 朱璐璐 王晟

孙亚军, 徐智敏, 李鑫, 张莉, 陈歌, 赵先鸣, 高雅婷, 刘琪, 张尚国, 汪韦峻, 朱璐璐, 王晟. 我国煤矿区矿井水污染问题及防控技术体系构建[J]. 煤田地质与勘探, 2021, 49(5): 1-16. doi: 10.3969/j.issn.1001-1986.2021.05.001
引用本文: 孙亚军, 徐智敏, 李鑫, 张莉, 陈歌, 赵先鸣, 高雅婷, 刘琪, 张尚国, 汪韦峻, 朱璐璐, 王晟. 我国煤矿区矿井水污染问题及防控技术体系构建[J]. 煤田地质与勘探, 2021, 49(5): 1-16. doi: 10.3969/j.issn.1001-1986.2021.05.001
SUN Yajun, XU Zhimin, LI Xin, ZHANG Li, CHEN Ge, ZHAO Xianming, GAO Yating, LIU Qi, ZHANG Shangguo, WANG Weijun, ZHU Lulu, WANG Sheng. Mine water drainage pollution in China's coal mining areas and the construction of prevention and control technical system[J]. COAL GEOLOGY & EXPLORATION, 2021, 49(5): 1-16. doi: 10.3969/j.issn.1001-1986.2021.05.001
Citation: SUN Yajun, XU Zhimin, LI Xin, ZHANG Li, CHEN Ge, ZHAO Xianming, GAO Yating, LIU Qi, ZHANG Shangguo, WANG Weijun, ZHU Lulu, WANG Sheng. Mine water drainage pollution in China's coal mining areas and the construction of prevention and control technical system[J]. COAL GEOLOGY & EXPLORATION, 2021, 49(5): 1-16. doi: 10.3969/j.issn.1001-1986.2021.05.001

 

“煤矿区矿井水污染防控及深部转移存储技术”专题 编者按:
  我国煤矿区极其复杂的水文地质条件导致差异明显、特征各异的地下水环境。受矿井开采扰动和矿井疏排水等影响,煤矿区的矿井水污染和生态环境影响问题日益受到国家有关部门和煤炭企业的重视。近年来,国家政策和地方管理推动了煤矿区环境的改善,鼓励实现煤–水双资源协调开采,凸显出煤矿区地下水环境演化及矿井水污染防治方面的良好基础和研究前景。本刊依托中国矿业大学孙亚军教授负责的国家重点研发计划项目“煤矿区场地地下水污染防控材料与技术”(NO.2019YFC1805400)在煤矿区矿井水环境污染防控方面取得的阶段性系列研究成果,结合部分其他学者的相关科研成果设立本专题,选登6篇相关论文,以展现我国煤矿水文地质工作者在上述领域的最新研究进展和观点,以期引起学术界和产业界的更多关注和讨论,加速推进矿井水污染防控与矿区地下水环境保护方面的研究。

我国煤矿区矿井水污染问题及防控技术体系构建

doi: 10.3969/j.issn.1001-1986.2021.05.001
基金项目: 

国家重点研发计划项目 2019YFC1805400

中央高校基本科研业务费专项资金项目 2020ZDPY0201

详细信息
    第一作者:

    孙亚军,1963年生,男,安徽涡阳人,博士,教授,博士生导师,研究方向为矿井水害防治与污染防控. E-mail: syj@cumt.edu.cn

  • 中图分类号: X52; P641

Mine water drainage pollution in China's coal mining areas and the construction of prevention and control technical system

  • 摘要: 煤炭开采必然产生大量的矿井涌水,我国目前的矿井水整体上表现出水质相对较差、水处理成本较高等问题。首先明确了我国典型矿区矿井水水质的主体特征:常规离子是造成矿井水水质差的主要化学组分;矿井水中有毒有害物质占比小,且基本优于地下水Ⅲ类水质量标准。其次,详细探讨了我国矿井水水质形成、演化的几个科学问题,包括不同水文地质结构下物理–化学作用所起的主导作用,时间效应对水质演化的影响,微生物群落结构特征及其与环境因素的相关关系,水动力场–化学场–微生物场–温度场的多场耦合问题等。接着重点介绍矿井水污染防控的技术方法,以减少矿井突(涌)水量和水资源保护为前提,以实现煤–水双资源协调开采、煤炭绿色开采为目标,以矿井水“阻断、减量、保护”为主要防控思路,围绕煤矿区矿井水阻断技术、污染负荷减量技术、污染区修复治理等科学问题展开分析;通过各种现有技术、方法、工艺,最大可能地降低吨煤矿井水处理成本,如采用井下预处理、地面深度处理、超深回灌封贮、生态资源化利用等。最后,提出研发煤矿区地下水及污染物的阻断材料和吸附材料、注浆装备、监测设备、投料设备、原位取样检测设备等,形成我国煤矿区矿井水污染防控技术体系。该技术体系的构建可对煤矿绿色开采、煤矿区深层地下水污染防控、闭坑矿井水污染防控、矿区地下水资源及生态环境保护利用等提供理论及技术支撑。

     

  • 图  矿井水形成的概念模式

    Fig. 1  Conceptual model of the formation of mine water drainage

    图  山东某矿老空水中SO42-含量变化

    Fig. 2  Variation of SO42- content in goaf water of a mine in Shandong Province

    图  矿井水污染防控技术体系

    Fig. 3  Mine water pollution prevention and control technical system

    图  我国“十三五”期间闭坑矿井数量

    Fig. 4  The number of mine closures during the 13th Five-Year Plan period

    表  1  我国部分矿区矿井水水质总体特征

    Table  1  Overall characteristics of mine water quality at some mining areas of China 单位: mg/L

    典型矿区 项目 K+ Na+ Ca2+ Mg2+ Cl- SO42- HCO3- NO3- 悬浮物 pH TDS 氟化物
    两淮矿区 数据量 51 51 51 52 51 51 44 49 6
    数据范围 10.50~1 514.14 2.81-331.60 2.19-120.60 1.80~2 631.35 1.00~1 447. 39.70~1 391.83 6.50-9.13 190.00~4 949.21 0.57-2.54
    中位数 332.00 52.30 26.18 245.50 116.16 370.37 8.20 1 585.66 1.48
    算术平均数 426.62 70.43 35.01 422.16 176.02 477.76 8.19 1 632.37 1.59
    鲁西南矿区 数据量 20 23 23 26 35 25 6 1 31 27 1
    数据范围 0.002~313.00 11.40~781.60 6.60-271.00 21.60~354.90 0.002~3 410.10 0~695.00 4.00-408.00 94.00 1.80~8.56 544.00~4 331.10 0.91
    中位数 80.95 276.60 116.00 52.75 1 031.70 256.00 15.52 7.51 2 111.40
    算术平均数 102.75 279.93 110.45 92.89 1 042.36 219.44 78.87 6.71 2 081.32
    山西矿区 数据量 28 72 83 80 80 84 73 29 8 44 75 7
    数据范围 2.80~160.70 36.24~958.94 0.24~975.30 0~1 657.00 8.06-342.02 2.26-10 080.40 12.52~1 566.49 0~15.00 72.65~239.90 2.75~11.61 286.00~12 247.00 0.25-3.58
    中位数 17.56 274.15 107.79 28.74 66.01 345.34 497.54 1.20 153.91 7.69 1 525.00 0.40
    算术平均值 22.85 307.99 187.26 114.55 89.34 858.35 546.40 3.27 153.89 6.89 1 721.12 1.25
    黄陇矿区 数据量 1 1 1 2 6 1 10 23 24 2 3
    数据范围 571.85 59.60 27.50 45.10~246.40 210.00~921.00 239.50 0.91-7.00 50.00~622.00 6.60-9.00 1 143.00~20578.00 0.60~1 595.00
    中位数 145.75 240.50 1.64 288.00 8.04 10 860.50 0.74
    算术平均值 145.75 351.00 2.21 286.10 7.92 10 860.50 0.97
    河南矿区 数据量 13 4 16 16 16 16 16 1 7 12 1
    数据范围 15.13~1215.81 10.32~197.80 2.81~349.08 3.52~138.02 10.95~590.25 27.37-2 786.09 227.21~570.84 0.73 7.15-8.30 333.04~4 949.26 1.51
    中位数 70.90 70.40 83.56 30.17 21.62 110.95 346.15 7.55 756.00
    算术平均值 300.67 87.23 116.77 38.63 87.48 542.36 378.23 7.68 1 554.40
    冀中矿区 数据量 23 14 23 23 23 23 23 1 3 16
    数据范围 0.90~1 104.20 7.60~82.40 18.60~287.80 2.80~893.80 14.65-2 121.90 26.26-2 006.10 152.10~667.30 83.25 7.13~8.70 345.20~6 330.50
    中位数 1.60 16.00 82.60 22.40 28.40 80.70 261.20 7.30 490.30
    算术平均值 111.17 26.03 102.45 59.85 183.72 218.89 287.91 7.71 1 095.34
    云贵矿区 数据量 11 11 11 11 11 16 11 11 42 66 11 8
    数据范围 0.90-12.30 0.70~3.70 77.84~144.00 8.02-99.12 3.81-10.00 100.00~2 903.85 0~158.00 1.66-30.36 34.00~1 296.00 2.40-8.83 292.53-2 402.81 0.20-2.60
    中位数 4.10 1.00 104.30 39.18 6.19 961.95 9.83 365.50 4.96 1 066.20 1.80
    算术平均值 5.17 1.25 110.60 46.80 6.67 1 174.00 12.12 385.67 5.20 1 118.80 1.43
    神东矿区 数据量 2 2 2 2 1 1 1 4 3 5 1 6
    数据范围 1.00-35.70 7.25-518.00 22.08~76.00 4.00-20.00 2.11-37.01 4.26~23.46 125.90~213.70 0.68-41.23 1.50~2 025.00 7.57-8.40 131.00~258.00 0.26-12.75
    中位数 6.00 236.80 47.00 13.06 0.87 404.00 7.70
    算术平均值 11.59 249.71 48.20 12.53 10.91 810.17 7.89
    宁东矿区 数据量 1 1 1 1 2 3 1 3 6 8 1
    数据范围 1.60-26.30 436.44~1218.50 43.39~424.80 78.66~318.18 141.05~1869.18 267.21~1878.95 4.67~234.00 24.00~92.00 6.95~9.65 185.20~6 247.00 2.20
    中位数 882.24 1 240.35 64.00 2 762.50
    算术平均值 1 005.11 1 245.00 60.00 8.19 2 911.27
    新疆矿区 数据量 1 1 1 5 2 1 3 4 7 4
    数据范围 5 332.11 716.02 440.44 42.80~7 110.30 12.00~6 643.00 337.51 16.00~2 378.00 6.14~8.70 410.00~21 404.00 0.21~0.37
    中位数 154.20 0.28
    算术平均值 1 558.96 0.29
    蒙东矿区 数据量 1 1 1 1 4 5 1 2 9 13 4 10
    数据范围 3.14 127.07 8.03 1.78 21.73-2 480.00 12.45~1 160.00 343.08 10.10~57.59 7.00~1 080.00 6.62-7.95 293.90~1 012.38 0.42~2 320.00
    中位数 90.19 40.76 34.84 160.00 7.46 570.71 1.26
    算术平均值 670.53 295.93 34.84 284.11 7.38 625.66 233.24
    典型矿区 项目 COD BOD 石油类 有机污染物 NH4+ Fe Mn Cu As Pb 有益元素 放射性元素(Bq/L)
    两淮矿区 数据量 11 9 7 5
    数据范围 0.06-2.63 0.002~48.86 0.000 14~0.09 1.33-9.07
    中位数 1.18 0.31 0.001 4.05
    算术平均数 0.67 11.01 0.016 4.83
    鲁西南矿区 数据量 6 3 1 3 8 1 1
    数据范围 0.57-600.00 1.74~20.00 15.00 0.10~1.01 0.50-478.00 26.00 0.02
    中位数 2.20 14.15 0.22 15.10
    算术平均数 112.37 11.96 0.44 91.20
    山西矿区 数据量 13 8 4 17 9 14
    数据范围 2.53-292.00 0.45-9.00 0.15-1.65 0.12~1 368.80 2.59~12 994.00 0.05~74.50
    中位数 49.80 2.69 0.39 2.79 1025.00 0.41
    算术平均值 83.13 3.80 0.65 195.09 3 080.68 16.48
    黄陇矿区 数据量 23 22 22 9 10 2 1 6 7 6
    数据范围 21.00~385.00 3.82-132.00 0.05-3.50 0.005~0.029 0.18-4.75 0.09-0.22 0.28 0.006 5~0.009 6 0.001~0.013 0.004 1~0.005 3
    中位数 188.00 62.75 0.41 0.007 1.51 0.16 0.008 8 0.008 2 0.004 6
    算术平均值 182.13 52.83 0.75 0.012 1.86 0.16 0.008 6 0.006 2 0.004 6
    河南矿区 数据量 1 1 1
    数据范围 4.79 0.18 0.07
    中位数
    算术平均值
    冀中矿区 数据量
    数据范围
    中位数
    算术平均值
    云贵矿区 数据量 53 8 27 12 37 53 4 33 4 8
    数据范围 1.44~839.47 1.80-13.60 0.01~4.64 0.86-50.70 0~1 166.00 0.05-30.00 2.50-4.58 0.000 3-0.60 0.25-0.69 0.003~0.010
    中位数 66.00 2.20 0.06 3.30 48.30 1.50 3.30 0.005 0.48 0.003
    算术平均值 111.87 3.59 0.54 19.02 117.04 3.57 3.42 0.07 0.48 0.004
    神东矿区 数据量 4 4 4 1 1
    数据范围 2.20~181.60 4.60~808.00 8.40-17.00 0.002 0.033
    中位数 11.73 408.20 14.50
    算术平均值 51.81 407.25 13.60
    宁东矿区 数据量 3 1
    数据范围 122.00~278.00 0.06~0.12
    中位数 125.00 0.09
    算术平均值 175.00 0.09
    新疆矿区 数据量 2 2 2 1 1 3 1
    数据范围 8.00-358.00 0-2.98 0.039~0.078 0.05 0.004 0-0.05 α≤1,总β≤10
    中位数
    算术平均值
    蒙东矿区 数据量 9 1 8 11 1 6
    数据范围 1.65~1 270.00 1.20 0.27-0.58 0.31-33.59 5.00 0.001~0.071
    中位数 21.55 0.46 0.70 0.01
    算术平均值 149.37 0.46 3.96 0.02
    注:pH值无量纲。
    下载: 导出CSV
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  • 收稿日期:  2021-08-15
  • 修回日期:  2021-08-30
  • 发布日期:  2021-10-25
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