Gray correlation evaluation of geological environment in the open-pit coal mine concentration area based on remote sensing:A case study of the Zhungeer Coalfield
GAO Junhua1,2(), LIU Shasha1,2, YANG Jinzhong3, ZHAO Mingpeng1,2, LIU Xinyue1,2, ZOU Lianxue1,2
1. Hunan Provincial General Station of Geological Environment Monitoring, Changsha 410007, China 2. Hunan Natural Resources Affairs Center, Changsha 410004, China 3. China Aero Geophysical Survey and Remote Sensing Center for Natural Resources, Beijing 100083, China
Satellite remote sensing technology has been used in China for more than ten years to obtain annual national mine geological environment remote sensing monitoring data. How to make full use of existing remote sensing monitoring results to carry out large-scale mining geological environmental assessment zoning is worthy of discussion and research. Therefore, the Zhungeer Coalfield was taken as the research area, and the artificial interpolation and hierarchical weighted improved gray correlation method was used to evaluate and analyze the geological environment of the 16 open-pit coal mines in the area, and the evaluation level divisions based on the mines were obtained. The evaluation conclusion is that the 3 mines of Huilong, Mengxiang and Liangjiaqi are severely affected by the environment, and the 5 mines of Tianciyuan, Weijiamao, Tingziyan, Liuhuliang and Heidaigou have relatively high environmental impacts. In the severe areas, 8 mines of Harwusu, Jinzhengtai, Zhaofu, Yongsheng, Cui’ergezui, Hongran, Huafu and Zhengren are general environmental impact areas, and other non-mine areas are the non-influenced areas. The evaluation results can reflect the geological environment status of the Zhungeer coalfield relatively objectively. Therefore, the gray correlation evaluation method of mine geological environment could be popularized and applied in a large area or even in whole China.
高俊华, 刘莎莎, 杨金中, 赵明鹏, 刘欣悦, 邹联学. 基于遥感的露天煤矿集中区地质环境灰关联评价——以准格尔煤田为例[J]. 国土资源遥感, 2021, 33(1): 183-190.
GAO Junhua, LIU Shasha, YANG Jinzhong, ZHAO Mingpeng, LIU Xinyue, ZOU Lianxue. Gray correlation evaluation of geological environment in the open-pit coal mine concentration area based on remote sensing:A case study of the Zhungeer Coalfield. Remote Sensing for Land & Resources, 2021, 33(1): 183-190.
Ministry of Land and Resources. DZ/T0223-2011 mine geological environmental protection and restoration and control plan preparation specifications[S]. Beijing:Department of Geology and Environment,Ministry of Land and Resources, 2011.
Jiang S L, Sun S Q, Wang H. Comprehensive assessment of mine environmental quality of Anhui Province[J]. Journal of Hefei University of Technology, 2008,31(1):112-115.
Yang M Z, Liu L, Gao R L. Application of fuzzy synjournal evaluation to the environmental influence of the west mineral exploration[J]. Journal of Xi’an University of Science and Technology, 2006,26(4):439-442.
Jiang F L, Zhou K P, Li X Y, et al. Study on assessment of geological environment impact in mines based on set pair analysis[J]. Mining and Metallurgical Engineering, 2009,29(2):1-4.
Xin J J, Zhang T, Gao H Q, et al. The application of grey system theory in land quality evaluation[J]. System Sciemces and Comprehensive Studies in Agriculture, 1987(12):39-46.
Meng X L, Sun L X, Zhou D, et al. Application and improvement of grey theory for assessment of environmental quality[J]. Journal of Harbin Institute of Technology, 2002,10(5):700-702.
Xiao X B, Xu X G. A Study on grey associative analysis for assessment of surface water quality[J]. Environmental Science and Technology, 2003,5(3):34-36.
Wu K Y, Li R Z, Chen X J. Grey relation projection model for the evaluation of regional eco-environmental quality[J]. Resources and Environment in the Yangtze River Basin, 2003,9(5):473-478.
Liu D C, Jin X P, Zhou Z L. Application of grey degree of association evaluation method in ground fissures in Tongzhou District of Beijing[J]. Chinese Journal of Geological Hazard and Control, 2010,9(3):73-76.
Huang Y Q, Wei C, He J Y. Mine environmental quality evaluation by grey relational analysis method in Jiangxi Province[J]. Resources Survey and Environment, 2012,4(4):268-273.
[14]
刘方. 基于灰色关联度的模糊层次组合矿山地质环境评价模型研究[D]. 西安:长安大学, 2014.
Liu F. Study on fuzzy hierarchical combination mine geological environment assessment model based on grey correlation[D]. Xi’an:Chang’an University, 2014.
[15]
焦明连. 基于灰色聚类分析的矿山环境质量评价[J]. 煤矿开采, 2016,4(2):78-82.
Jiao M L. Evaluation of mine environment quality based on gray cluster analysis[J]. Coal Mining, 2016,4(2):78-82.
Yang J Z, Nie H F, Jing Q Q. Preliminary analysis of mine geo-environment status and existing problems in China[J]. Remote Sensing for Land and Resources, 2017,29(2):1-7.doi: 10.6046/gtzyyg.2017.02.01.
Yang J Z, Nie H F, Wang H Q, et al. Remote sensing monitoring of mine geological environment in China (2015)[M]. Beijing: Surveying and Mapping Press, 2017.
Yang J Z, Wang H, Dong S F, et al. Remote sensing monitoring of mine geological environment in China (2016)[M]. Beijing: Geological Publishing House, 2018.
Yang J Z, Wang X H, Wang H Q, et al. Remote sensing monitoring of mine geological environment in China (2017)[M]. Beijing: Geological Publishing House, 2019.
Wang H Q, Wu M D, Liu Q, et al. Remote sensing monitoring of mining land in a certain area of Shanxi Province[J]. Remote Sensing for Land and Resources, 2018,30(1):116-120.doi: 10.6046/gtzyyg.2018.01.16.
Yang X H, Huang J, Tian L, et al. Application of mine remote sensing monitoring to analysis of mine goaf stability[J]. Remote Sensing for Land and Resources, 2018,30(3):143-150.doi: 10.6046/gtzyyg.2018.03.20.
Zhao Y L, Yang J Z, Yin Y Q, et al. Research on remote sensing monitoring of zirconium-titanium sand mine exploitation and strategies of ecological restoration on the eastern beach of Hainan Island[J]. Remote Sensing for Land and Resources, 2019,31(4):143-150.doi: 10.6046/gtzyyg.2019.04.19.
Wang J, Yin Y Q, Yu H, et al. Remote sensing monitoring of mine geological environment in Zhejiang Province based on RS and GIS[J]. Remote Sensing for Land and Resources, 2020,32(1):232-236.doi: 10.6046/gtzyyg.2020.01.31.
Ma S B, Li S H, An P, et al. Remote sensing monitoring and quality evaluation for the mine geological environment of the Juhugeng coal mining area in Qinghai Province[J]. Remote Sensing for Land and Resources, 2015,27(2):139-145.doi: 10.6046/gtzyyg.2015.02.22.
Zhao Y L. Study and application of analytic hierarchy process of mine geological environment:A case study in Hainan Island[J]. Remote Sensing for Land and Resources, 2020,32(1):148-153.doi: 10.6046/gtzyyg.2020.01.20.
Li W H, Gong J H. Quantitative simulation for difference between true surface area and planimetric area[J]. Application Research of Computers, 2008,4(4):983-985.
[29]
吴子武. 内蒙准格尔煤田地质特征[J]. 煤田地质与勘探, 1981(10):16-18.
Wu Z W. Geological characteristics of Zhungeer Coalfield,Inner Mongolia[J]. Coal Geology and Exploration, 1981(10):16-18.
Gao S H. Environmental geology and disaster prevention in Zhungeer mining area, Inner Mongolia[C]// Selected Papers of the Fourth National Engineering Geology Congress(3). 1992: 1168-1172.
Zhang L, Wang X D. Study on ecological security problems and countermeasures in Junger Coalfield[J]. Journal of North China Institute of Science and Technology, 2010(1):40-43.
Luo Z H. A method for predicting the environmental impact of land desertification in the phase I project of Zhungeer Coalfield[J]. Journal of Ningxia University(Natural Science Edition), 1993,9(3):42-47.
Hunan Provincial Bureau of Quality and Technical Supervision. DB43/T 1042—2015 specifications for the preparation of comprehensive prevention and control plans for mine geological environment[S]. Changsha:Hunan Provincial General Station for Geological Environment Monitoring, 2015.