Coal Geology & Exploration
Abstract
The mining and depletion of coal resources have a certain degree of impact on the environment and population of the coal mining area. Confronted with the resources and environment problems, China strongly advocates the construction of green mines, requiring that mine exploitation must be within resources and environment carrying capacity. With the support of multi-source data (Landsat 8, GF-2, etc.) and socio-economic statistics data, Analytic Hierarchy Process was used to construct an index system for evaluating resources and environment carrying capacity of the mining area in Xilinhot, Inner Mongolia from two aspects of the carrying background and the carrying statu. Among them, the carrying background is expressed by the proportion of available resources, and the carrying state is calculated by coal mine economic proportion index, coal mine employment index, mining damage index, waste discharge intensity and development restriction index which plays a regulatory role. In addition, different countermeasures and recommendations were proposed for different carrying capacities in the mining area. The results show that the carrying capacity of the Xilinhot’s mining area is “medium” for both the Shengli No.1 coal mine and East No.2 coal mine’ and “small” for the West No.2 coal mine. The resources and environment carrying capacity of the mining area occupies the medium-sized level on the lower side in Xilinhot, Inner Mongolia in 2016. It is necessary to enhance restoration efforts to promote the simultaneous development of economy and environment while mining. The study results are of guiding significance for the restoration and management of the mining environment. What’s more, it also provides a reference for the evaluation of the resources and environment carrying capacity of small-scale mining areas.
Keywords
coal mining area, resource and environment, carrying capacity evaluation, multi-source data, index system, sustainable development, Xilinhot mining area of Inner Mongolia
DOI
10.12363/issn.1001-1986.21.11.0682
Recommended Citation
SUN Jundong, SONG Renzhong, LI Feiyue,
et al.
(2022)
"Evaluation of resources and environment carrying capacity of Xilinhot mining area based on multi-source data,"
Coal Geology & Exploration: Vol. 50:
Iss.
7, Article 19.
DOI: 10.12363/issn.1001-1986.21.11.0682
Available at:
https://cge.researchcommons.org/journal/vol50/iss7/19
Reference
[1] 陈向国. 我国基础能源:煤炭的“清”“高”之路[J]. 节能与环保,2016(5):16−25. CHEN Xiangguo. My country’s basic energy:The road to “clear”and“high”coal[J]. Energy Conservation & Environmental Protection,2016(5):16−25.
[2] 段启兵. 浅谈煤矿开采对周围环境的影响[J]. 内蒙古煤炭经济,2020(13):151−152. DUAN Qibing. Talking about the impact of coal mining on the surrounding environment[J]. Inner Mongolia Coal Economy,2020(13):151−152.
[3] 徐勇,张雪飞,周侃,等. 资源环境承载能力预警的超载成因分析方法及应用[J]. 地理科学进展,2017,36(3):277−285. XU Yong,ZHANG Xuefei,ZHOU Kan,et al. Method and application of cause analysis for early–warning of resource and environmental system overloading[J]. Progress in Geography,2017,36(3):277−285.
[4] SLEESE M. Enhancement of carrying capability options[M]. London:The Resource Use Institute,1990.
[5] MC KEON G M,STONE G S,SYKTUS J I,et al. Climate change impacts on northern Australian rangeland livestock carrying capacity:A review of issues[J]. The Rangeland Journal,2009,31(1):1−29.
[6] WIDODO B,LUPYANTO R,SULISTIONO B,et al. Analysis of environmental carrying capacity for the development of sustainable settlement in Yogyakarta urban area[J]. Procedia Environmental Sciences,2015,28:519−527.
[7] 秦鹏,沈智慧,白喜庆. 神北矿区环境承载力评价[J]. 煤田地质与勘探,2011,39(1):36−40. QIN Peng,SHEN Zhihui,BAI Xiqing. The analysis of regional environmental carrying capacity of Shenbei mining area[J]. Coal Geology & Exploration,2011,39(1):36−40.
[8] 殷全增,陈中山,冯启言,等. 河北省主要矿区关闭煤矿资源再利用模式探讨[J]. 煤田地质与勘探,2021,49(6):113−120. YIN Quanzeng,CHEN Zhongshan,FENG Qiyan,et al. Discussion on the recommended models for resource reuse of closed coal mines in main mining areas of Hebei Province[J]. Coal Geology & Exploration,2021,49(6):113−120.
[9] 毛汉英,余丹林. 环渤海地区区域承载力研究[J]. 地理学报,2001,56(3):363−371. MAO Hanying,YU Danlin. Regional carrying capacity in Bohai Rim[J]. Acta Geographica Sinica,2001,56(3):363−371.
[10] 诸宁扬,丁生喜,葛丽亚. 基于人口资源环境承载力评价的青海省重点开发区域新型城镇化问题[J]. 江苏农业科学,2017,45(1):279−285. ZHU Ningyang,DING Shengxi,GE Liya. New urbanization issues in the key development areas of Qinghai Province based on the evaluation of population,resources and environmental carrying capacity[J]. Jiangsu Agricultural Sciences,2017,45(1):279−285.
[11] 赵晨艳,张杜鹃. 基于生态足迹的长治县资源环境承载力评价研究[J]. 山西科技,2017,33(3):30−32. ZHAO Chenyan,ZHANG Dujuan. Research on Changzhi County resources environment bearing capacity evaluation based on ecological footprint[J]. Shanxi Science and Technology,2017,33(3):30−32.
[12] 何苏玲,王金亮,角媛梅,等. 国土空间规划视角下资源环境承载力评价分析:以昆明市为例[J]. 中国农业资源与区划,2021,43(4):119−128. HE Suling,WANG Jinliang,JIAO Yuanmei,et al. Resource and environmental carrying capacity evaluation analysis under the perspective of territory development planning:A case study of Kunming city[J]. Chinese Journal of Agricultural Resources and Regional Planning,2021,43(4):119−128.
[13] 蒋仁伟,谈树成. 基于GIS的白马红格矿区地质环境承载力研究[J]. 金属矿山,2019(5):170−176. JIANG Renwei,TAN Shucheng. Study on the geological environmental bearing capacity of Baimahongge mining area based on GIS[J]. Metal Mine,2019(5):170−176.
[14] 付颖琪,王里奥,黄川,等. 中国西北高原某金矿区环境承载力评价[J]. 矿业研究与开发,2019,39(6):141−149. FU Yingqi,WANG Li’ao,HUANG Chuan,et al. Assessment of environmental carrying capacity of a gold mining area in northwest plateau of China[J]. Mining Research and Development,2019,39(6):141−149.
[15] 闫旭骞,徐俊艳. 矿区资源环境承载力评价方法研究[J]. 金属矿山,2005(6):56−59. YAN Xuqian,XU Junyan. Assessment method of resources and environment carrying capability in mining areas[J]. Metal Mine,2005(6):56−59.
[16] 陈志超,高函,刘昌华. 基于AHP综合评价模型的潞安矿区生态承载力评价[J]. 湖北农业科学,2013,52(17):4062−4065. CHEN Zhichao,GAO Han,LIU Changhua. Assessment of ecological carrying capacity in Lu’an mining area based on AHP model[J]. Hubei Agricultural Sciences,2013,52(17):4062−4065.
[17] 孙顺利,周科平,胡小龙. 基于投影评价方法的矿区资源环境承载力分析[J]. 中国安全科学学报,2007,17(5):139−143. SUN Shunli,ZHOU Keping,HU Xiaolong. Analysis of mineral resources environmental carrying capacity based on projection methods[J]. China Safety Science Journal,2007,17(5):139−143.
[18] 黄秋香. 矿区资源环境承载力评价指标体系及评价方法[J]. 矿业研究与开发,2009,29(1):62−64. HUANG Qiuxiang. Assessment method and indexes system of resources and environment carrying capacity in mining areas[J]. Mining Research and Development,2009,29(1):62−64.
[19] 张成业,李军,雷少刚,等. 矿区生态环境定量遥感监测研究进展与展望[J]. 金属矿山,2021(3):1−27. ZHANG Chengye,LI Jun,LEI Shaogang,et al. Progress and prospect of the quantitative remote sensing for monitoring the eco−environment in mining area[J]. Metal Mine,2021(3):1−27.
[20] 李军,彭苏萍,张成业,等. 矿区生态环境定量遥感监测评价技术框架与应用[J]. 矿业科学学报,2022,7(1):9−25. LI Jun,PENG Suping,ZHANG Chengye,et al. Quantitative remote sensing–based monitoring and evaluation of the ecological environment in mining areas:Technology framework and application[J]. Journal of Mining Science and Technology,2022,7(1):9−25.
[21] 邹蕴,贺晓,赵金花,等. 我国北方草原区露天煤炭开采对周边草原群落的影响:以锡林浩特市西二矿为例[J]. 干旱区资源与环境,2019,33(8):199−203. ZOU Yun,HE Xiao,ZHAO Jinhua,et al. The effect of open–pit coal mining on the surrounding grassland communities in north China:Case of west second open–pit mine in Xilinhot[J]. Journal of Arid Land Resources and Environment,2019,33(8):199−203.
[22] 孙俊东. 胜利一号露天矿采区转向方式优化研究[J]. 煤炭工程,2021,53(9):11−15. SUN Jundong. Optimization of mining area steering scheme in Shengli No.1 open–pit coal mine[J]. Coal Engineering,2021,53(9):11−15.
[23] 苏楞高娃,朝鲁孟其其格,锡林塔娜,等. 矿产开采对草原景观生态的影响:以锡林浩特市周边矿区为例[J]. 草原与草业,2013,25(3):40−43. SULENG Gaowa,CHAOLU Mengqiqige,XILIN Tana,et al. The impact of mineral mining on grassland landscape ecology:Case on mining areas around Xilinhot City[J]. Grassland and Prataculture,2013,25(3):40−43.
[24] 李军,桑潇,张成业,等. 资源型城市长时间序列土壤含水量变化分析:以锡林浩特市为例[J]. 测绘通报,2021(7):17−22. LI Jun,SANG Xiao,ZHANG Chengye,et al. Analysis of soil moisture content changes in resource–based cities over a long time series:A case study of Xilinhot City[J]. Bulletin of Surveying and Mapping,2021(7):17−22.
[25] 王奕森,夏树涛. 集成学习之随机森林算法综述[J]. 信息通信技术,2018,12(1):49−55. WANG Yisen,XIA Shutao. A survey of random forests algorithms[J]. Information and Communications Technologies,2018,12(1):49−55.
[26] LIU Shengwei,PENG Dailiang,ZHANG Bing,et al. The accuracy of winter wheat identification at different growth stages using remote sensing[J]. Remote Sensing,2022,14(4).
[27] 布仁仓,常禹,胡远满,等. 基于Kappa系数的景观变化测度:以辽宁省中部城市群为例[J]. 生态学报,2005,25(4):778−784. BU Rencang,CHANG Yu,HU Yuanman,et al. Measuring spatial information changes using Kappa coefficients:A case study of the city groups in central Liaoning Province[J]. Acta Ecologica Sinica,2005,25(4):778−784.
[28] 陈荣,韩浩武,傅佩红,等. 基于多时相遥感影像和随机森林算法的土壤制图[J]. 土壤,2021,53(5):1087−1094. CHEN Rong,HAN Haowu,FU Peihong,et al. Soil mapping based on multi−temporal remote sensing images and random forest algorithm[J]. Soils,2021,53(5):1087−1094.
[29] 张永林,蔡昌盛. 基于再分析资料ERA5的对流层延迟估计方法及精度评估[J]. 大地测量与地球动力学,2020,40(1):62−65. ZHANG Yonglin,CAI Changsheng. Method and accuracy assessment of zenith tropospheric delay derived from ERA5 re–analysis data[J]. Journal of Geodesy and Geodynamics,2020,40(1):62−65.
[30] SAATY T L. A scaling method for priorities in hierarchical structures[J]. Journal of Mathematical Psychology,1977,15(3):234−281.
[31] 国土资源部. 国土资源环境承载力评价技术要求(试行):[2016]1213[S]. 北京:国土资源部,2016.
[32] 王党朝,申莹莹,杨震. 胜利一号露天煤矿开发建设对生态环境的影响评价[J]. 中国煤炭,2020,46(1):58−66. WANG Dangchao,SHEN Yingying,YANG Zhen. Evaluation of the impact of development and construction of Shengli No.1 open–pit coal mine[J]. China Coal,2020,46(1):58−66.
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