Coal Geology & Exploration
Abstract
Background Dust pollution emerges as a major environmental challenge in the open-pit mining of coal mines. Ecological restoration has found widespread applications in mining areas as a crucial measure. However, there is a lack of systematic studies on the role of vegetation configuration in dust migration. Methods Using the computational fluid dynamics (CFD) method for numerical simulation, this study constructed a comprehensive simulation framework incorporating wind field reconstruction, dust migration, and the dust retention capacity of vegetation. By setting different particle sizes and wind speeds, this study systematically analyzed dust migration patterns. Furthermore, vegetation configuration was introduced into the simulation framework as a variable, and its effects on wind field distribution and dust migration were investigated. Results and Conclusions The results indicate that the wind field distribution in a mining pit exhibited significant spatial heterogeneity. Specifically, the central portion of the wind field showed relatively uniform wind speeds, while dust was primarily concentrated in the vortex zones at its edges. The dust migration was jointly controlled by particle size and wind speed. In detail, dust of fine particles featured high dispersion capacity and could maintain significant concentrations even at a distance of hundreds of meters downwind, emerging as a primary factor in regional pollution. In contrast, dust of coarse particles was subjected to gravity, primarily settling at the pit bottom and near the surface. Therefore, it exerted a limited impact on distant areas. Under high wind speeds, some particles would be re-suspended by strong winds, thereby increasing the risk of long-distance migration. Vegetation configuration played an important role in dust retention. Regarding vegetation types, a mixed tree-shrub configuration performed best. Tall trees could reduce near-surface wind speeds, while low shrubs captured dust particles at the bottom. As a result, the combination of both reduced the peak concentration of inhalable particles by over 50%. In terms of vegetation layout, the staggered pattern created more favorable conditions for disrupting airflow channels compared to the linear pattern, leading to the formation of small-scale vortex zones with low wind speeds in the vegetation coverage areas. Therefore, this pattern prolonged the retention of particles and promoted their settling, reducing the average dust concentration by about 25% while significantly narrowing the range of local areas with high dust concentrations. The results of this study can serve as a theoretical guide for vegetation configuration optimization, as well as dust pollution prevention and control, in the ecological restoration of open-pit coal mines.
Keywords
open-pit coal mine, ecological restoration, vegetation configuration, numerical simulation, dust migration, influence pattern
DOI
10.12363/issn.1001-1986.25.06.0481
Recommended Citation
HAN Li, LI Renjie, BI Yinli,
et al.
(2025)
"Numerical simulations of the influence of vegetation configuration on dust migration in open-pit coal mines,"
Coal Geology & Exploration: Vol. 53:
Iss.
10, Article 9.
DOI: 10.12363/issn.1001-1986.25.06.0481
Available at:
https://cge.researchcommons.org/journal/vol53/iss10/9
Reference
[1] 于海旭,刘闯,金磊,等. 世界露天煤矿发展综述[J]. 中国煤炭,2023,49(6):116−125.
YU Haixu,LIU Chuang,JIN Lei,et al. Overview of the development of open–pit coal mines in the world[J]. China Coal,2023,49(6):116−125.
[2] 程卫民,周刚,陈连军,等. 我国煤矿粉尘防治理论与技术20年研究进展及展望[J]. 煤炭科学技术,2020,48(2):1−20.
CHENG Weimin,ZHOU Gang,CHEN Lianjun,et al. Research progress and prospect of dust control theory and technology in China’s coal mines in the past 20 years[J]. Coal Science and Technology,2020,48(2):1−20.
[3] 卢洁,雷少刚. 露天煤矿粉尘环境影响及其扩散规律研究综述[J]. 煤矿安全,2017,48(8):231−234.
LU Jie,LEI Shaogang. Research overview of effect of dust on environment and its diffusion laws in open–pit coal mine[J]. Safety in Coal Mines,2017,48(8):231−234.
[4] 康小春. 露天煤矿粉尘危害与起尘机理及其治理措施研究[J]. 工程技术,2025(2):149−152.
[5] 樊强,李素英,关塔拉,等. 露天煤矿生产中产生的粉尘对周边植物和土壤的影响[J]. 北方环境,2013,25(9):104−108.
FAN Qiang,LI Suying,GUAN Tala,et al. The ecological effect on plant and soil around opencast coal mine from the mineral dust[J]. Northern Environmental,2013,25(9):104−108.
[6] 王桂林,李明超,毕银丽,等. 排土场不同培肥模式团聚体有机碳的累积效应[J]. 水土保持通报,2024,44(3):307−316.
WANG Guilin,LI Mingchao,BI Yinli,et al. Accumulation effect of aggregate organic carbon from different fertilization modes at open–pit mine dumpsites[J]. Bulletin of Soil and Water Conservation,2024,44(3):307−316.
[7] 赵晨曦,王玉杰,王云琦,等. 细颗粒物(PM2.5)与植被关系的研究综述[J]. 生态学杂志,2013,32(8):2203–2210.
ZHAO Chenxi,WANG Yujie,WANG Yunqi,et al. Interactions between fine particulate matter (PM2.5) and vegetation:A review[J]. Chinese Journal of Ecology,2013,32(8):2203–2210.
[8] 赵勇,李树人,阎志平. 城市绿地的滞尘效应及评价方法[J]. 华中农业大学学报,2002,21(6):582−586.
ZHAO Yong,LI Shuren,YAN Zhiping. The effect of greenland on absorbed dust and its assessment method[J]. Journal of Huazhong Agricultural University,2002,21(6):582−586.
[9] ZHANG Jieming,YU Xinxiao,JIA Guodong,et al. Determination of optimum vegetation type and layout for soil wind erosion control in desertified land in North China[J]. Ecological Engineering,2021,171:106383.
[10] CHANG Xiaomin,SUN Libo,YU Xinxiao,et al. Windbreak efficiency in controlling wind erosion and particulate matter concentrations from farmlands[J]. Agriculture Ecosystems & Environment,2021,308:107269.
[11] MIRI A,DAVIDSON–ARNOTT R. The effectiveness of a single Tamarix tree in reducing aeolian erosion in an arid region[J]. Agricultural and Forest Meteorology,2021,300:108324.
[12] 毕银丽,刘涛. 露天矿区植被协同演变多源数据时序分析:以准格尔矿区为例[J]. 煤炭科学技术,2022,50(1):293−302.
BI Yinli,LIU Tao. Time series analysis of multi–source data of coordinated evolution of vegetation in open–pit mining area:Taking Junggar mining area as an example[J]. Coal Science and Technology,2022,50(1):293−302.
[13] 王桂林. 基于FLUENT数值模拟的露天煤矿坑底粉尘浓度分布特征[J]. 煤炭工程,2020,52(12):80−84.
WANG Guilin. Distribution of dust concentration at the bottom of open–pit coal mine based on FLUENT simulation[J]. Coal Engineering,2020,52(12):80−84.
[14] 田冬梅,吴汐瑶,姚建,等. 安太堡露天矿坑粉尘运移规律模拟分析[J]. 华北科技学院学报,2025,22(1):61−68.
TIAN Dongmei,WU Xiyao,YAO Jian,et al. Simulation and analysis of dust transport pattern in the open pit of Antaibu mine[J]. Journal of North China Institute of Science and Technology,2025,22(1):61−68.
[15] WU Tong,YANG Zhuo,WANG Aiai,et al. A study on movement characteristics and distribution law of dust particles in open–pit coal mine[J]. Scientific Reports,2021,11(1):14703.
[16] 范舒欣,晏海,齐石茗月,等. 北京市26种落叶阔叶绿化树种的滞尘能力[J]. 植物生态学报,2015,39(7):736−745.
FAN Shuxin,YAN Hai,QI Shimingyue,et al. Dust capturing capacities of twenty–six deciduous broad–leaved trees in Beijing[J]. Chinese Journal of Plant Ecology,2015,39(7):736−745.
[17] HUO Hongyuan,CHEN Fei. Study of effects of different vegetation model parameter settings on quantitative CFD simulation of urban spatial air temperature and wind–field[J]. International Journal of Remote Sensing,2024,45(19/20):7234−7247.
[18] HE Chenchen,SHAO Wenyan. Numerical simulation of shelter effect assessment for single–row windbreaks on the periphery of oasis farmland[J]. Journal of Arid Environments,2024,222:105165.
[19] YANG Hongyu,CHEN Taihan,LIN Yuanyuan,et al. Integrated impacts of tree planting and street aspect ratios on CO dispersion and personal exposure in full–scale street canyons[J]. Building and Environment,2020,169:106529.
[20] 汤万钧. 露天煤矿粉尘分布和运移机理研究[D]. 徐州:中国矿业大学,2018.
TANG Wanjun. Study on dust distribution and diffusion mechanism in open pit coal mine[D]. Xuzhou:China University of Mining and Technology,2018.
[21] 郑霞忠,杨丘,晋良海,等. 露天料场爆破粉尘质量浓度时空分布特征数值模拟[J]. 中国安全科学学报,2020,30(10):55−62.
ZHENG Xiazhong,YANG Qiu,JIN Lianghai,et al. Numerical simulation on spatio–temporal distribution regularities of blasting dust mass concentration in open quarry[J]. China Safety Science Journal,2020,30(10):55−62.
[22] 王义. 神东矿区生态保护技术与实践[M]. 北京:化学工业出版社,2023.
[23] 梁敏阳. 哈尔乌素露天煤矿冬季粉尘运移规律及数值模拟[D]. 徐州:中国矿业大学,2019.
LIANG Minyang. Dust migration law and numerical simulation in winter in Haerwusu open–pit coal mine[D]. Xuzhou:China University of Mining and Technology,2019.
[24] 王志明. 哈尔乌素露天煤矿冬季坑底粉尘污染特征及扩散规律[D]. 徐州:中国矿业大学,2021.
WANG Zhiming. Pollution characteristics and diffusion law of dust at the pit bottom in Haerwusu open–pit coal mine in winter[D]. Xuzhou:China University of Mining and Technology,2021.
[25] MAHGOUB A O,GHANI S. Numerical and experimental investigation of utilizing the porous media model for windbreaks CFD simulation[J]. Sustainable Cities and Society,2021,65:102648.
[26] 周甲男,郑颖娟,马苏,等. 神东矿区不同恢复模式下植物多样性特征[J]. 环境科学研究,2024,37(12):2771−2781.
ZHOU Jianan,ZHENG Yingjuan,MA Su,et al. Characteristics of plant diversity in the Shendong mining area under different restoration modes[J]. Research of Environmental Sciences,2024,37(12):2771−2781.
[27] 张黄情. 风流影响下露天矿爆堆处粉尘全区域分布规律研究[D]. 重庆:重庆大学,2023.
ZHANG Huangqing. Study on the whole area distribution law of dust at the explosive pile in open pit mine under the influence of wind flow[D]. Chongqing:Chongqing University,2023.
[28] HUANG Zhihui,GE Shaocheng,JING Deji,et al. Numerical simulation of blasting dust pollution in open–pit mines[J]. Applied Ecology and Environmental Research,2019,17(5):10313−10333.
[29] LI Lin,ZHANG Ruixin,LI Quansheng,et al. Multidimensional spatial monitoring of open pit mine dust dispersion by unmanned aerial vehicle[J]. Scientific Reports,2023,13(1):6815.
[30] 杨玉新. 深凹露天矿粉尘污染及扩散规律分析[J]. 矿业工程,2003,1(5):48−51.
YANG Yuxin. Regularity of pollution caused by dust diffusion in stope of deep–digging open pit mine[J]. Mining Engineering,2003,1(5):48−51.
[31] 柴一新,祝宁,韩焕金. 城市绿化树种的滞尘效应:以哈尔滨市为例[J]. 应用生态学报,2002,13(9):1121−1126.
CHAI Yixin,ZHU Ning,HAN Huanjin. Dust removal effect of urban tree species in Harbin[J]. Chinese Journal of Applied Ecology,2002,13(9):1121−1126.
Included in
Earth Sciences Commons, Mining Engineering Commons, Oil, Gas, and Energy Commons, Sustainability Commons