摘要排土场修复是矿山生态修复取得突破性进展和显著成效的关键之一。为进一步优选排土场生态修复技术组合,支撑矿山生态修复和绿色矿山建设,以薛家湾—龙口镇露天煤矿5个不同修复技术组合排土场板块为研究对象,选取生态效益和经济效益2类9个评价指标,运用层次分析(analytic hierarchy process,AHP)法和优劣解距离(technique for order preference by similarity to an ideal solution,TOPSIS)法构建排土场生态修复效果综合评价模型,确定最终权重并进行综合评价。研究区排土场修复最优解决方案为: 工程措施采用平整覆土+挡水围堰+坡面整形+条播技术; 植被措施采用柳树+沙打旺+草木犀+苜蓿+冰草+老芒麦。研究表明,在矿山生态修复效果的成效评价中,使用定性加定量的评价方法,能更好地反映出生态修复效果,可为科学评价生态修复效果提供支撑。
Abstract:Waste dump restoration is one of the key points restricting the breakthrough progress of mine ecological restoration. In order to further optimize the technical combination of waste dump ecological restoration, and support mine ecological restoration and green mine construction, the authors in this paper chose 5 waste dump sectors with different restoration technologies as the study case. Nine evaluation indexes in the categories of ecological benefit and economic benefit were selected and AHP and TOPSIS methods were used to construct a comprehensive evaluation system and determine the final weight and conduct comprehensive evaluation. The results showed that the optimal solution for waste dump restoration in the study area was using the engineering measures as flat soil covering + water retaining cofferdam + slope shaping + strip seeding technology, and the vegetation measures as willow + cladawang + grass luteus + alfalfa + ice grass + laomangmai. During the process of mine ecological restoration effect evaluation, using the qualitative and quantitative evaluation methods could better reflect the ecological restoration effect and provide support for the scientific evaluation of ecological restoration effect.
[1] 张琳,陆兆华,唐思易,等.露天煤矿排土场边坡植被组成特征及其群落稳定性评价[J].生态学报,2021,41(14):5764-5774. Zhang L,Lu Z H,Tang S Y,et al.Slope vegetation characteristics and community stability at different restoration years of open-pit coal mine waste dump[J].Acta Ecologica Sinica,2021,41(14):5764-5774. [2] 颜建东,李玥.采煤活动对土地资源影响的现状及其可持续发展——以山西焦煤集团东曲煤矿为例[J].中小企业管理与科技(上旬刊),2019(8):56-57. Yan J D,Li Y.Present situation of the influence of coal mining activities on land resources and its sustainable development:Taking Dongqu coal mine of Shanxi coking coal group as an example[J].Management & Technology of SME,2019(8):56-57. [3] 汤银锁. 矿山地质灾害区的生态恢复治理研究[D].唐山:华北理工大学,2020. Tang Y S.Study on Ecological Restoration and Management of Mine Geological Disaster Area[D].Tangshan:North China University of Science and Technology,2020. [4] 董佳慧,牛瑞卿,亓梦茹,等.InSAR技术和孕灾背景指标相结合的地灾隐患识别[J].地质科技通报,2022,41(2):187-196. Dong J H,Niu R Q,Qi M R,et al.Identification of geological hazards based on the combination of InSAR technology and disaster background indicators[J].Bulletin of Geological Science and Technology,2022,41(2):187-196. [5] 王杨扬,赵中秋,原野.露天煤矿复垦中生物多样性响应研究进展[J].中国矿业,2017,26(S1):148-153. Wang Y Y,Zhao Z Q,Yuan Y.Research progress on biodiversity response in reclamation of open coal mines[J].China Mining Magazine,2017,26(S1):148-153. [6] 谭晓东,张紫昭,张利飞,等.新疆哈巴河县某金属矿山地质环境保护与土地复垦治理措施[J].世界有色金属,2021(5):186-187. Tan X D,Zhang Z Z,Zhang L F,et al.Geological environment protection and land reclamation measures of a metal mine in Habahe County,Xinjiang[J].World Nonferrous Metals,2021(5):186-187. [7] 李晓莹. 唐山铁尾矿植被恢复生态效益分析与评价[D].保定:河北农业大学,2014. Li X Y.The Ecological Efficiency Analysis and Evaluation of Revegetation in Iron Tailings in Tangshan[D].Baoding:Hebei Agricultural University,2014. [8] 李鹏飞. 基于无人机遥感的排土(矸)场立地对植被盖度影响研究[D].北京:北京林业大学,2020. Li P F.Influence Study of Sites on Vegetation Coverage in Dumps and Gangue Fields Based on UAV Remote Sensing Techno-logy[D].Beijing:Beijing Forestry University,2020. [9] 张昕. 乌海、灵武排土(矸)场生态修复模式LFA评价研究[D].北京:北京林业大学,2020. Zhang X.Study on LFA Evaluation of Ecological Restoration Models of Wuhai and Lingwu Disposal(waste) Fields[D].Beijing:Beijing Forestry University,2020. [10] 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 Y L,Liu T.Time series analysis of multi-source data of coordinated evolution of vegetation in open-pit mining area:Taking Jungar Mining Area as an example[J].Coal Science and Technology,2022,50(1):293-302. [11] 李喜,殷坤龙,陈标典,等.武汉白沙洲长江两岸岩溶塌陷易发性评价与地铁建设过程中的防治对策[J].地质科技通报,2020,39(6):121-130. Li X,Yin K L,Chen B D,et al.Evaluation of susceptibility to karst collapse on both sides of the Yangtze River in Baishazhou,Wuhan and preventive measures in the process of metro construction[J].Bulletin of Geological Science and Technology,2020,39(6):121-130. [12] 赵玉灵. 基于层次分析法的矿山环境评价方法研究——以海南岛为例[J].国土资源遥感,2020,32(1):148-153. Zhao Y L.Study and application of analytic hierarchy process of mine geological environment:A case study of Hainan Island[J].Remote Sensing for Land & Resources,2020,32(1):148-153. [13] 丁鸿浩,赖宁静,邓林昊,等.基于AHP-TOPSIS最优组合赋权的闽侯县生态敏感性评价[J].中国城市林业,2022,20(3):94-101. Ding H H,Lai N J,Deng L H,et al.Ecological sensitivity evaluation of Minhou county based on AHP-TOPSIS optimal combination weighting[J].Journal of Chinese Urban Forestry,2022,20(3):94-101. [14] Toebe M,Machado L N,Tartaglia F L,et al.Sample size for estimating mean and coefficient of variation in species of crotalarias[J].Anais da Academia Brasileira de Ciências,90(2):1705-1715. [15] Ayyoub H N,Khoo M B C,Saha S,et al.Multivariate coefficient of variation charts with measurement errors[J].Computers & Industrial Engineering,2020,147:106633. [16] Alaee N H,Mozafari A,Mirzaee M,et al.Fuzzy evaluation method for the identification of subsidence susceptibility in an underground mine (case study in Tabas coal mine of Iran)[J].Natural Hazards,2019,99(2):797-806. [17] Xing Y H,Li S,Liao J J,et al.Suitability evaluation of rural tourism based on AHP and fuzzy evaluation method[J].IOP Conference Series:Earth and Environmental Science,2019,267(3):032007. [18] Cui X L.Coal mine flood risk analysis based on fuzzy evaluation method[J].Journal of Physics Conference Series,2018,1176(4):042095. [19] Cui X L.Coal mine flood risk analysis based on fuzzy evaluation method[J].Journal of Physics Conference Series,2018,1176(4):042095. [20] Xia P,Ying C Y.Research on the stability evaluation method of anchored slopes based on group decision making and matter element analysis[J].Scientific Reports,2021,11(1):16588. [21] Xie X F,Pu L J.Assessment of urban ecosystem health based on matter element analysis:a case study of 13 cities in Jiangsu province,China[J].International Journal of Environmental Research and Public Health,2017,14(8):940. [22] Wang Y S,Anderson N,Torgashov E.Selection of geophysical methods based on matter-element analysis with analytic hierarchy process[J].Exploration Geophysics,2021,52(6):669-679. [23] 季贵斌,梁力,赵颖.高速公路边坡混播植被群落生态适应性综合评价[J].安全与环境学报,2016,16(6):360-365. Ji G B,Liang L,Zhao Y.Evaluation for the ecological adaptability of the mixed vegetation group of highway slopes[J].Journal of Safety and Environment,2016,16(6):360-365. [24] 赵金召,张兆长,李艳晨,等.基于层次分析法的矿山高陡岩质边坡生态修复绿化效果评价研究[J].中国矿业,2022,31(4):80-85. Zhao J Z,Zhang Z C,Li Y C,et al.Evaluation of ecological restoration and greening effect of mine high and steep rock slope based on analytic hierarchy process[J].China Mining Magazine,2022,31(4):80-85. [25] 韩琳,李永峰,巫长悦,等.基于遥感生态指数的宝日希勒露天矿区生态修复效果评估[J].中国矿业,2022,31(4):54-61. Han L,LI Y F,Wu C Y,et al.Evaluation of ecological restoration effect in Baorixile Open-pit Mine Area based on remote sensing ecological index[J].China Mining Magazine,2022,31(4):54-61. [26] 董飞洋. 露天煤矿排土场不同植被恢复措施对坡面水土流失的影响[D].呼和浩特:内蒙古农业大学,2021. Dong F Y.Influence of Different Vegetation Restoration Measures on Soil and Water Loss on Slope of Open-pit Mine Dump[D].Hohhot:Inner Mongolia Agricultural University,2021. [27] 宫鹤忆. 黑岱沟露天煤矿排土场土壤保水性能和养分改良研究[D].上海:华东师范大学,2021. Gong H Y.Study on Soil Water Holding Capacity and Nutrient Improvement of Dumping Site in Open Pit Coal Mine of Heidaigou[D].Shanghai:East China Normal University,2021. [28] 杨帆. 矿区外排土场生态修复及其环境价值评价[D].赣州:江西理工大学,2009. Yang F.Ecological Restoration and Environmental Value Evaluation of Dump Outside Mining Area[D].Ganzhou:Jiangxi University of Science and Technology,2009. [29] 高俊华,刘莎莎,杨金中,等.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 J H,Liu S S,Yang J Z,et al.Gray correlation evaluation of geological environment in the open-pit coal mine concentration area based on remote sensing:A case study of Zhungeer Coal-field[J].Remote Sensing for Land & Resources,2021,33(1):183-190. [30] 李潇,吴克宁,刘亚男,等.基于生态系统服务的山水林田湖草生态保护修复研究——以南太行地区鹤山区为例[J].生态学报,2019,39(23):8806-8816. Li X,Wu K N,Liu Y N,et al.Ecological protection and restoration of mountains-rivers-forests-farmlands-lakes-grasslands based on ecosystem services: Taking Heshan section of Southern Taihang as an example[J].Acta Ecologica Sinica,2019,39(23):8806-8816. [31] 高云峰,徐友宁,祝雅轩,等.矿山生态环境修复研究热点与前沿分析——基于VOSviewer和CiteSpace的大数据可视化研究[J].地质通报,2018,37(12):2144-2153. Gao Y F,Xu Y N,Zhu Y X,et al.An analysis of the hotspot and frontier of mine eco-environment restoration based on big data visualization of VOSviewer and CiteSpace[J].Geological Bulletin of China,2018,37(12):2144-2153. [32] 戴永久,上官微.中国土壤有机质数据集[EB/OL].(2021-04-19).https://data.tpdc.ac.cn/en/data/8ba0a731-5b0b-4e2f-8b95-8b29cc3c0f3a/. Dai Y J,Shangguan W.Dataset of soil properties for land surface modeling over China[EB/OL].(2021-04-19).https://data.tpdc.ac.cn/en/data/8ba0a731-5b0b-4e2f-8b95-8b29cc3c0f3a/.