•  
  •  
 

Coal Geology & Exploration

Abstract

Background The northern sand prevention belt (NSPB) of China is primarily distributed in arid and semi-arid regions such as Xinjiang, Inner Mongolia, Ningxia, and Gansu. This belt exhibits scarce rainfall and intense evaporation, which lead to a shortage of water resources and vulnerable ecosystems. In recent years, the large-scale development of open-pit coal mines has caused increasingly violent mining disturbance in this belt, as well as increasingly prominent issues such as a decline in regional groundwater levels and ecological contradictions. To address technical challenges in balancing coal exploitation and water resource conservation in this belt, there is an urgent need to develop a technology system for water resource conservation in open-pit coal mining areas. Methods and Results This study investigated the distribution of open-pit coal mines in the NSPB and revealed the regional hydrogeological characteristics such as rainfall, evaporation, water-bearing media, water inflow, and water quality in three typical regions of the NSPB: eastern Inner Mongolia, western Inner Mongolia, and northern Xinjiang. It developed key technologies for the conservation of multiple water sources, including surface water, groundwater, atmospheric condensate water, and mine water in open-pit coal mining areas. These key technologies include (1) a multi-level mine water storage model that integrates surface reservoirs, reinjection into the Quaternary aquifer, and subsurface reservoirs; (2) the interception and storage of surface water; (3) the efficient capture and utilization of atmospheric condensate water; (4) groundwater source control dominated by curtain grouting, and (5) the artificial reconstruction of ecological aquifers in open-pit mining areas. As a result, a technology for three-dimensional water resource conservation in open-pit mining areas is formed. Additionally, this study explored technologies for the treatment of substantial suspended solids in mine water, low-cost and large-scale mine water treatment, and novel ecological precision irrigation in open-pit mining areas. Conclusions By establishing a three-dimensional, low-cost, efficient, large-scale, and replicable model for the conservation, treatment, and utilization of water resources for open-pit coal mines in the NSPB and developing a proactive and systematic technical integration system for the conservation, storage, and utilization of surface and subsurface water resources, this study contributes greatly to address the ecological restoration challenges in mining areas characterized by drought and scarce rainfall in the NSPB. The results of this study hold great significance for ensuring water supply for ecological conservation and restoration in the NSPB and for serving national strategies such as energy security and ecological civilization construction.

Keywords

open-pit coal mining, multi-level water storage, technology for three-dimensional water resource conservation, water resource utilization, mine water treatment, irrigation and utilization, northern sand prevention belt (NSPB)

DOI

10.12363/issn.1001-1986.25.03.0193

Reference

[1] 祝萍,刘鑫,郑瑜晗,等. 北方重点生态功能区生态系统服务权衡与协同[J]. 生态学报,2020,40(23):8694−8706.

ZHU Ping,LIU Xin,ZHENG Yuhan,et al. Tradeoffs and synergies of ecosystem services in key ecological function zones in northern China[J]. Acta Ecologica Sinica,2020,40(23):8694−8706.

[2] 中国能源中长期发展战略研究项目组. 中国能源中长期发展战略研究:综合卷[M]. 北京:科学出版社,2011.

[3] 姚强岭,于利强,陈胜焱,等. 西部生态脆弱矿区采动水资源与生态环境效应[J]. 煤炭学报,2025,50(2):748−767.

YAO Qiangling,YU Liqiang,CHEN Shengyan,et al. Mining–affected water resources and ecological effects in ecologically fragile mining areas of western China[J]. Journal of China Coal Society,2025,50(2):748−767.

[4] 曹志国,张建民,王皓,等. 西部矿区煤水协调开采物理与情景模拟实验研究[J]. 煤炭学报,2021,46(2):638−651.

CAO Zhiguo,ZHANG Jianmin,WANG Hao,et al. Physical modelling and scenario simulation of coal & water co–mining in coal mining areas in western China[J]. Journal of China Coal Society,2021,46(2):638−651.

[5] 刘贤斌,袁成健,姜仁坤. 我国煤炭开采中的水污染现状与对策[J]. 内蒙古煤炭经济,2024(5):46−48.

[6] 董书宁,王海,黄选明,等. 基于保障生态地下水位的露天煤矿主动保水技术研究[J]. 煤炭科学技术,2021,49(4):49−57.

DONG Shuning,WANG Hai,HUANG Xuanming,et al. Research on active water conservation technology in open–pit coal mine based on ecological protection groundwater level[J]. Coal Science and Technology,2021,49(4):49−57.

[7] 李颖,杨卓,吴桐. 露天煤矿疏干–回灌水帷幕保水采煤模式探讨[J]. 煤田地质与勘探,2021,49(6):160−166.

LI Ying,YANG Zhuo,WU Tong. Discussion on the water–preserved coal mining by dewatering–reflooding water curtain in open–pit coal mines[J]. Coal Geology & Exploration,2021,49(6):160−166.

[8] 李全生,张凯. 我国能源绿色开发利用路径研究[J]. 中国工程科学,2021,23(1):101−111.

LI Quansheng,ZHANG Kai. The path for green development and utilization of energy in China[J]. Strategic Study of CAE,2021,23(1):101−111.

[9] 李全生. 东部草原区大型煤电基地开发的生态影响与修复技术[J]. 煤炭学报,2019,44(12):3625−3635.

LI Quansheng. Progress of ecological restoration and comprehensive remediation technology in large–scale coal–fired power base in the eastern grassland area of China[J]. Journal of China Coal Society,2019,44(12):3625−3635.

[10] 李全生,许亚玲,李军,等. 采矿对植被变化的影响提取与生态累积效应量化分析[J]. 煤炭学报,2022,47(6):2420−2434.

LI Quansheng,XU Yaling,LI Jun,et al. Extraction of the impact of mining on vegetation changes and quantitative analysis of ecological cumulative effects[J]. Journal of China Coal Society,2022,47(6):2420−2434.

[11] 李全生,李淋. 东部草原区露天煤矿减损开采与生态系统修复技术及应用[J]. 煤炭科学技术,2023,51(1):484−492.

LI Quansheng,LI Lin. Technology and application of damage reduction mining and ecosystem restoration of open–pit coal mines in eastern grassland area[J]. Coal Science and Technology,2023,51(1):484−492.

[12] 李全生,韩兴,赵英,等. 露天煤矿植被修复关键技术集成与应用研究:以胜利露天矿外排土场为例[J]. 环境生态学,2021,3(6):47−53.

LI Quansheng,HAN Xing,ZHAO Ying,et al. Research on integration and application of key technologies of vegetation restoration in open–pit coal mine:A case study of external dump of Shengli opencast coal mine[J]. Environmental Ecology,2021,3(6):47−53.

[13] 李树志,郭孝理,李学良,等. 我国东部草原区露天矿排土场仿自然地貌土地整形方法[J]. 煤炭学报,2019,44(12):3636−3643.

LI Shuzhi,GUO Xiaoli,LI Xueliang,et al. Land reshaping method of imitating natural geomorphology for open–pit mine dump in eastern grassland area of China[J]. Journal of China Coal Society,2019,44(12):3636−3643.

[14] 宋子岭,范军富,王来贵,等. 露天煤矿开采现状及生态环境影响分析[J]. 露天采矿技术,2016,31(9):1−4.

SONG Ziling,FAN Junfu,WANG Laigui,et al. Impact analysis on mining status and ecological environment in open–pit coal mine[J]. Opencast Mining Technology,2016,31(9):1−4.

[15] 杜勇志,范业承,刘昊,等. “水量平衡分析”的露天煤矿水资源综合利用途径[J]. 中国矿业,2021,30(增刊1):94−100.

DU Yongzhi,FAN Yecheng,LIU Hao,et al. Comprehensive utilization of water resources in open pit coal mine based on“water balance analysis”[J]. China Mining Magazine,2021,30(Sup.1):94−100.

[16] 罗明,刘世梁,高岩,等. 基于自然的解决方案在北方防沙带生态屏障建设中的应用[J]. 生态学报,2024,44(8):3121−3131.

LUO Ming,LIU Shiliang,GAO Yan,et al. Application of the nature–based solutions concept in the ecological barrier construction in the northern sand prevention belt[J]. Acta Ecologica Sinica,2024,44(8):3121−3131.

[17] 刘智杰,王宏利. 为生态修复开出地质良方[N]. 中国自然资源报,2022-03-03(7).

[18] 李全生,李淋,方杰,等. 北方防沙带大型露天煤矿区生态保护与修复技术[J]. 煤炭科学技术,2024,52(1):323−333.

LI Quansheng,LI Lin,FANG Jie,et al. Ecological protection and restoration technology of large–scale open–pit coal mining area in the northern sand–proof belt[J]. Coal Science and Technology,2024,52(1):323−333.

[19] 时旭阳. 基于泥岩–地聚合物的露天矿隔水层重构机理及应用研究[D]. 徐州:中国矿业大学,2019.

SHI Xuyang. Research on reconstruction mechanism and application of aquiclude in open–pit mine based on mudstone–geopolymer[D]. Xuzhou:China University of Mining and Technology,2019.

[20] 李原园,李云玲,郭旭宁,等. 1956—2016年中国水资源总量时空分布规律及变化特征[J]. 水科学进展,2025,36(1):18−27.

LI Yuanyuan,LI Yunling,GUO Xuning,et al. Spatial–temporal distribution and variation characteristics of water resources in China during 1956—2016[J]. Advances in Water Science,2025,36(1):18−27.

[21] 罗涵予. 抚顺东露天矿环境现状评价及生态恢复规划[D]. 长春:吉林大学,2014.

LUO Hanyu. The evaluation on environmental status and planning of ecological restoration of the east strip coal mine in Fushun[D]. Changchun:Jilin University,2014.

[22] 石炳兴,石光,沈毅,等. “双碳”目标下蒙东草原地区露天煤矿绿色矿山建设[J]. 露天采矿技术,2023,38(6):1−4.

SHI Bingxing,SHI Guang,SHEN Yi,et al. Green mine construction of open–pit coal mine in the grassland area of eastern Inner Mongolia under the goal of “double carbon”[J]. Opencast Mining Technology,2023,38(6):1−4.

[23] 杨建,蒲悦. 我国西部矿井涌水分布特征及充水模式研究[J/OL]. 煤炭科学技术,2025:1–13 [2025-01-16]. https://kns.cnki.net/KCMS/detail/detail.aspx?filename=MTKJ20241219002&dbname=CJFD&dbcode=CJFQ.

YANG Jian,PU Yue. Research on the distribution characteristics and water filling modes of mine water inflow in western mining areas of China[J/OL]. Coal Science and Technology,2025:1–13 [2025-01-16]. https://kns.cnki.net/KCMS/detail/detail.aspx?filename=MTKJ20241219002&dbname=CJFD&dbcode=CJFQ.

[24] 马稚桐. 鄂尔多斯盆地风沙滩区土壤–地下水蒸发研究[D]. 西安:长安大学,2019.

MA Zhitong. Research on soil–groundwater evaporation in the wind–blown sand area of Ordos Basin[D]. Xi’an:Chang’an University,2019.

[25] 卢娜,万力. 基于RS的鄂尔多斯北部盆地地表蒸发量的计算[J]. 地质通报,2008,27(8):1165−1167.

LU Na,WAN Li. Calculation of the amount of surface evapotranspiration in the northern Ordos Basin,China,based on remote sensing[J]. Geological Bulletin of China,2008,27(8):1165−1167.

[26] 赵振宏,张俊. 鄂尔多斯盆地白垩系地下水系统多层结构研究[J]. 人民黄河,2013,35(2):42−44.

ZHAO Zhenhong,ZHANG Jun. Multilayer structure of groundwater flow systems in large thick aquifer of Ordos Cretaceous Basin[J]. Yellow River,2013,35(2):42−44.

[27] 侯光才,梁永平,尹立河,等. 鄂尔多斯盆地地下水系统及水资源潜力[J]. 水文地质工程地质,2009,36(1):18−23.

HOU Guangcai,LIANG Yongping,YIN Lihe,et al. Groundwater systems and water resources potential in the Ordos Basin[J]. Hydrogeology & Engineering Geology,2009,36(1):18−23.

[28] 高翔. 新疆准东典型煤矿区土壤环境质量评价及环境容量预测[D]. 徐州:中国矿业大学,2023.

GAO Xiang. Evaluation of soil environmental quality and prediction of environmental capacity in the typical coal mining area of Zhundong,Xinjiang[D]. Xuzhou:China University of Mining and Technology,2023.

[29] 王卫卫. 新疆天山谷地典型露天矿地下水控制与防洪排涝研究[J]. 露天采矿技术,2018,33(4):75−78.

WANG Weiwei. Study of groundwater control and flood control in typical open–pit mine of Xinjiang Tianshan[J]. Opencast Mining Technology,2018,33(4):75−78.

[30] 吴晓军,冯光俊,高海涛,等. 新疆大南湖七号煤矿顶板突水危险性评价与防治[J]. 煤矿安全,2018,49(9):252−256.

WU Xiaojun,FENG Guangjun,GAO Haitao,et al. Roof water inrush risk evaluation and prevention in Xinjiang Dananhu No.7 Coal Mine[J]. Safety in Coal Mines,2018,49(9):252−256.

[31] 刘侃. 新疆准南煤田某煤矿火烧区的水文地质特征[J]. 内蒙古煤炭经济,2017(19):141−144.

LIU Kan. Hydrogeological characteristics of burning area of a coal mine in Xinjiang south coalfield[J]. Inner Mongolia Coal Economy,2017(19):141−144.

[32] 李本军. 新疆地区煤矿矿井水文地质条件和防治水问题分析[J]. 中国煤炭地质,2022,34(增刊1):45−49.

LI Benjun. Analysis on hydrogeological conditions of coal mines and water prevention and control problem in Xinjiang coal mining area[J]. Coal Geology of China,2022,34(Sup.1):45−49.

[33] 张丹丹. 露天矿排土场径流区植被控制水土流失效应及评价研究[D]. 阜新:辽宁工程技术大学,2009.

ZHANG Dandan. The vegetation control soil erosion effect and evaluation research of the open–pit dump runoff area[D]. Fuxin:Liaoning Technical University,2009.

[34] 胡振琪. 矿山复垦土壤重构的理论与方法[J]. 煤炭学报,2022,47(7):2499−2515.

HU Zhenqi. Theory and method of soil reconstruction of reclaimed mined land[J]. Journal of China Coal Society,2022,47(7):2499−2515.

[35] 胡振琪. 煤矿山复垦土壤剖面重构的基本原理与方法[J]. 煤炭学报,1997,22(6):617−622.

HU Zhenqi. Principle and method of soil profile reconstruction for coal mine land reclamation[J]. Journal of China Coal Society,1997,22(6):617−622.

[36] 魏忠义,胡振琪,白中科. 露天煤矿排土场平台“堆状地面”土壤重构方法[J]. 煤炭学报,2001,26(1):18−21.

WEI Zhongyi,HU Zhenqi,BAI Zhongke. The loose–heaped–ground method of soil reconstruction on the stackpiles of open–pit coal mine[J]. Journal of China Coal Society,2001,26(1):18−21.

[37] 赵欣,王佟,王伟超,等. 青海木里矿区四号井生态地质修复与效果[J]. 煤田地质与勘探,2025,53(4):119−127.

ZHAO Xin,WANG Tong,WANG Weichao,et al. Measures and effects of eco-geological restoration in well No. 4 in the Muli mining area,Qinghai Province,China[J]. Coal Geology & Exploration,2025,53(4):119−127.

[38] 张玉锴,阎凯,李博,等. 中国土壤重构及其土水特性研究进展[J]. 农业资源与环境学报,2023,40(3):511−524.

ZHANG Yukai,YAN Kai,LI Bo,et al. Research progress on soil reconstruction and soil–water characteristics in China[J]. Journal of Agricultural Resources and Environment,2023,40(3):511−524.

[39] 张超英,陈艳鑫,耿玉清,等. 生物炭和保水剂对煤矸石基质水分物理特征的影响[J]. 干旱区资源与环境,2020,34(9):122−128.

ZHANG Chaoying,CHEN Yanxin,GENG Yuqing,et al. Effect of biochar and super water absorbents on water physical characteristics of coal gangue matrix[J]. Journal of Arid Land Resources and Environment,2020,34(9):122−128.

[40] DU Tao,WANG Dongmei,BAI Yujie,et al. Optimizing the formulation of coal gangue planting substrate using wastes:The sustainability of coal mine ecological restoration[J]. Ecological Engineering,2020,143:105669.

[41] LIU Ying,LEI Shaogang,CHEN Xiaoyang,et al. Study of plant configuration pattern in guided vegetation restoration:A case study of semiarid underground mining areas in western China[J]. Ecological Engineering,2021,170:106334.

[42] 王靖伟. 露天煤矿排土场地层重构试验研究[D]. 徐州:中国矿业大学,2019.

WANG Jingwei. Experimental study on stratum reconstruction of dump soil in open–pit coal mine[D]. Xuzhou:China University of Mining and Technology,2019.

[43] 石泉泉. 塔尔露天矿煤层底板重构隔水层防治水方法研究[D]. 徐州:中国矿业大学,2022.

SHI Quanquan. Research on waterproof method of reconstructed aquiclude in the coal seam floor of Taer open–pit mine[D]. Xuzhou:China University of Mining and Technology,2022.

[44] 雷少刚,夏嘉南,卞正富,等. 论露天矿区近自然生态修复[J]. 煤炭学报,2024,49(4):2021−2030.

LEI Shaogang,XIA Jianan,BIAN Zhengfu,et al. Near–natural ecological restoration in open–pit mine area[J]. Journal of China Coal Society,2024,49(4):2021−2030.

[45] 王建文,惠双林. 大型矿井建设中应重视的几个安全问题及安全管理措施[J]. 中国矿业,2012,21(增刊1):243−246.

WANG Jianwen,HUI Shuanglin. The important security problems and safety management measures in large–scale mine construction[J]. China Mining Magazine,2012,21(Sup.1):243−246.

[46] 马剑,马小真. 煤矿矿井水资源化及综合利用的实践思考[J]. 中国资源综合利用,2019,37(12):62−64.

MA Jian,MA Xiaozhen. Practical thinking on water resources utilization and comprehensive utilization in coal mine[J]. China Resources Comprehensive Utilization,2019,37(12):62−64.

[47] 胡立峰. 基于污染动态特征的新集矿区矿井水处理方案研究[D]. 淮南:安徽理工大学,2006.

HU Lifeng. Study of Xinji coal mine water treatment based on the dynamic contaminative characteristics[D]. Huainan:Anhui University of Science & Technology,2006.

[48] MAIHEMUTI B,WANG Enzhi,HUDAN T,et al. Numerical simulation analysis of reservoir bank fractured rock–slope deformation and failure processes[J]. International Journal of Geomechanics,2016,16(2):04015058.

[49] 王勇,吴丽,王雪冬. 化学混凝法处理阜新矿区矿井水试验研究[J]. 煤炭科学技术,2017,45(2):203−208.

WANG Yong,WU Li,WANG Xuedong. Experimental study on chemical coagulation of mine water in Fuxin mining area[J]. Coal Science and Technology,2017,45(2):203−208.

[50] 刘永峰,石炳兴,徐旭峰,等. 高寒地区露天矿矿坑水混凝试验研究[J]. 能源环境保护,2021,35(3):24−30.

LIU Yongfeng,SHI Bingxing,XU Xufeng,et al. Experimental study on pit water coagulation of open–pit mine in alpine area[J]. Energy Environmental Protection,2021,35(3):24−30.

[51] 徐树峰,霍建良,侯培雄,等. 超磁分离工艺在矿井水处理工程中的应用[J]. 煤炭工程,2021,53(10):31−34.

XU Shufeng,HUO Jianliang,HOU Peixiong,et al. Application of super–magnetic separation process in mine water treatment[J]. Coal Engineering,2021,53(10):31−34.

[52] 吕志国,易洋,肖波,等. 超磁分离在煤矿矿井水井下处理工程的应用[J]. 中国给水排水,2018,34(20):105−108.

LYU Zhiguo,YI Yang,XIAO Bo,et al. Engineering application of ultra–magnetic–separation technology in downhole treatment of coal mine water[J]. China Water & Wastewater,2018,34(20):105−108.

[53] 刘艳辉. 重介速沉工艺在含悬浮物矿井水处理中的应用[J]. 工业用水与废水,2019,50(2):49−51.

LIU Yanhui. Application of dense media loading coagulation and sedimentation in suspended solid–containing mine water treatment[J]. Industrial Water & Wastewater,2019,50(2):49−51.

[54] 谭金生,黄昌凤,郭中权. 高悬浮物高矿化度矿井水处理工艺及工程实践[J]. 能源环境保护,2013,27(3):30−32.

TAN Jinsheng,HUANG Changfeng,GUO Zhongquan. Treatment process and engineering practice for mine drainage water with high suspended solids and high salinity[J]. Energy Environmental Protection,2013,27(3):30−32.

[55] 程志伟,王碧清,田江鱼. 高悬浮物矿井水处理技术研究与应用[J]. 煤炭科学技术,2020,48(增刊1):278−282.

CHENG Zhiwei,WANG Biqing,TIAN Jiangyu. Research and application of high suspended solids mine water treatment technology[J]. Coal Science and Technology,2020,48(Sup.1):278−282.

[56] 郭德,张秀梅,吴大为. 高悬浮物矿井水处理工艺设计[J]. 给水排水,2003,29(6):48−50.

GUO De,ZHANG Xiumei,WU Dawei. Process design on treatment of mine pit water with high SS content[J]. Water & Wastewater Engineering,2003,29(6):48−50.

[57] 周争,赵丽,葛小鹏,等. 酸性矿井水中和沉淀法除铁优化[J]. 环境工程学报,2014,8(6):2347−2352.

ZHOU Zheng,ZHAO Li,GE Xiaopeng,et al. Optimizing iron removal of acidic mine draining water in neutralization and precipitation process[J]. Chinese Journal of Environmental Engineering,2014,8(6):2347−2352.

[58] 骆欣,敖燕环,杨怡心. 酸性矿井水中重金属处理技术研究进展[J]. 华北科技学院学报,2018,15(6):93−97.

LUO Xin,AO Yanhuan,YANG Yixin. Research progress of heavy metal treatment technology in acid drainage[J]. Journal of North China Institute of Science and Technology,2018,15(6):93−97.

[59] 徐建平,万海洮. 利用活性炭处理酸性矿井废水研究[J]. 水处理技术,2014,40(3):57−59.

XU Jianping,WAN Haitao. Study on the treatment of acid mine wastewater by activated carbon[J]. Technology of Water Treatment,2014,40(3):57−59.

[60] 万海洮,徐建平,王兆珺. 利用粉煤灰及改性粉煤灰处理酸性矿井水研究[J]. 水处理技术,2015,41(5):70−72.

WAN Haitao,XU Jianping,WANG Zhaojun. The treatment of acid mine wastewater by coal fly ash and modified coal fly ash[J]. Technology of Water Treatment,2015,41(5):70−72.

[61] 王浩,王淑璇,王甜甜. 矿井水生态灌溉适用性评价及污染组分去除研究[J]. 陕西煤炭,2024,43(7):30−37.

WANG Hao,WANG Shuxuan,WANG Tiantian. Evaluation of ecological irrigation applicability of mine water and study on the removal of pollutant components[J]. Shaanxi Coal,2024,43(7):30−37.

[62] 张丽星,周瑞平,海春兴,等. 矿井中水灌溉下土壤重金属的污染特征研究[J]. 中国环境科学,2023,43(10):5349−5358.

ZHANG Lixing,ZHOU Ruiping,HAI Chunxing,et al. Pollution characteristics of soil heavy metals with the irrigation of treated mine water[J]. China Environmental Science,2023,43(10):5349−5358.

[63] 仝泽文. 高盐矿井水资源化综合利用在高盐渍区荒漠造林中的试验研究[J]. 能源技术与管理,2023,48(5):136−139.

[64] 华岚英,夏夜,邹本东,等. 土壤重金属的污染来源、隐患与修复技术[J]. 环境生态学,2024,6(2):90−94.

HUA Lanying,XIA Ye,ZOU Bendong,et al. Pollution source,hidden dangers and remediation technologies of heavy metal in soil[J]. Environmental Ecology,2024,6(2):90−94.

Download Chinese Version

Share

COinS
 
 

To view the content in your browser, please download Adobe Reader or, alternately,
you may Download the file to your hard drive.

NOTE: The latest versions of Adobe Reader do not support viewing PDF files within Firefox on Mac OS and if you are using a modern (Intel) Mac, there is no official plugin for viewing PDF files within the browser window.