Abstract
The accurate determination of the height of the water-conducting fractured zone (HWCFZ) in a coal seam covered by thin bedrock and thick clay layer is crucial for aquifer protection, mine safety, and eco-environmental conservation. Using the Sanyuan coal mine in North China as a case study, theoretical analysis, numerical simulation, and field measurements were used to analyze the regularity of the HWCFZ in this area. Per mechanical theory, a geometrical model for calculating rock bending and subsidence was established. Two arcs of equal curvature and lengths and opposite curvature direction were used to fit the curve section of intermediate rock layer after bending. The theoretical method for solving the HWCFZ was given by calculating the rock layer's tensile ratio. In addition, rock failure process analysis (RFPA) software was used to simulate the development of the water-conducting fractured zone (WCFZ) during the mining process, and the HWCFZ was measured by the drilling fluid loss measurement, both which verified the feasibility of the theoretical calculation. To determine the primary controlling factors affecting the HWCFZ, the seepage characteristics and plastic properties of the Quaternary clay layer were also analyzed using laboratory tests. Results show that the Quaternary clay with a depth greater than 130 m has a permeability coefficient of E−10 m/s, a liquidity index less than 0.25, and a plasticity index more than 17, indicating the clay layer is impermeable and of great importance to inhibiting the development of WCFZ. The research can provide significant theoretical insights for effectively preventing water hazards on mine roofs.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Du F, Gao R (2017) Development patterns of fractured water-conducting zones in longwall mining of thick coal seams—a case study on safe mining under the Zhuozhang River. Energies 10:1856–1871
Duić N, Guzović Z, Kafarov V, Klemeš JJ, Mathiessen BV, Yan J (2013) Sustainable development of energy, water and environment systems. Appl Energy 101:3–5
Feng S, Sun S, Lv Y, Lv J (2011) Research on the height of water flowing fractured zone of fully mechanized caving mining in extra-thick coal seam. Procedia Eng 26:466–471
Huang WP, Gao YF, Wang B, Liu JR (2017) Evolution rule and development height of permeable fractured zone under combined-strata structure. J Min Saf Eng 34:330–335
Lai XP, Cai MF, Ren FH, Xie MW, Esaki T (2006) Assessment of rock mass characteristics and the excavation disturbed zone in the Lingxin Coal Mine beneath the Xitian river, China. Int J Rock Mech Min 43:572–581
Lai XP, Ren FH, Wu YP, Cai MF (2009) Comprehensive assessment on dynamic roof instability under fractured rock mass conditions in the excavation disturbed zone. Int J Min Met Mater 16:12–18
Li WP, Hua JM, Ye GJ, Duan ZH, Yang HK, Fu LQ, Zhao XJ (2000) Evaluation of present geological environment and prediction of its variation caused by mining in Yushenfu mine area of north Shaanxi. J Eng Geol 8:324–333
Li L, Tang C, Zhao X, Cai M (2014) Block caving-induced strata movement and associated surface subsidence: a numerical study based on a demonstration model. Bull Eng Geol Environ 73:1165–1182
Liu HY, Liu JX, Tang C (2001) Numerical simulation of failure process of overburden rock strata caused by mining excavation. Chin J Geotech Eng 23:201–204
Liu SL, Li WP, Wang QQ, Pei YB (2018a) Investigation on mining-induced fractured zone height developed in different layers above Jurassic coal seam in western China. Arab J Geosci 11:30–39
Liu SL, Li WP, Wang QQ (2018b) Height of the water-flowing fractured zone of the Jurassic Coal Seam in Northwestern China. Mine Water Environ 37:312–321
Liu TQ (1981) Surface movements, overburden failure and its application. Coal Industry Press, Beijing (in Chinese)
Liu W (2019) Experimental and numerical study of rock stratum movement characteristics in longwall mining. Shock Vib 2019:1–15
Liu XS, Tan YL, Ning JG, Tian CL, Wang J (2015) The height of water-conducting fractured zones in longwall mining of shallow coal seams. Geotech Geol Eng 33:693–700
Majdi A, Hassani F, Nasiri M (2012) Prediction of the height of destressed zone above the mined panel roof in longwall coal mining. Int J Coal Geol 98:62–72
Miao XX, Cui XM, Wang J, Xu JL (2011) The height of fractured water-conducting zone in undermined rock strata. Eng Geol 120:32–39
Palchik V (2003) Formation of fractured zones in overburden due to longwall mining. Environ Geol 44:28–38
Qian MG, Miao XX, Xu JL (1996) Theoretical study of key stratum in ground control. J China Coal Soc 21:225–230
Qian MG, Shi PW, Xu JL (2003) Mining pressure and strata control. China University of Mining and Technology Press, Xuzhou (in Chinese)
Qiao W, Li WP, Li T, Chang JY, Wang QQ (2017) Effects of coal mining on shallow water resources in semiarid regions: a case study in the Shennan mining area, Shaanxi, China. Mine Water Environ 36:104–113
Rezaei M, Hossaini M, Majdi A (2015) A time-independent energy model to determine the height of destressed zone above the mined panel in longwall coal mining. Tunn Undergr Space Tech 47:81–92
Tang C, Xu Z, Xu X (1999) Application of analysis system RFPA2D of rock fracture process in researching moving rules of covering workface. J Liaoning Tech Univ (Nat Sci) 18:456–458
Wang G, Wu MM, Wang R, Xu H, Song X (2017) Height of the mining-induced fractured zone above a coal face. Eng Geol 216:140–152
Wei JC, Wu FZ, Yin HY, Guo JB, Xie DL, Xiao LL, Zhi HF, Lefticariu L (2017) Formation and height of the interconnected fractures zone after extraction of thick coal seams with weak overburden in Western China. Mine Water Environ 36:59–66
Xu JL, Zhu WB, Wang XZ (2012) New method to predict the height of fractured water-conducting zone by location of key strata. J Chin Coal Soc 37:762–769
Xu YC (2004) Mechanics characteristics of deep saturated clay. J Chin Coal Soc 29:26–30 (in Chinese)
Xue S, Liu Y, Liu SL, Li WP, Wu YL, Pei YB (2018) Numerical simulation for groundwater distribution after mining in Zhuanlongwan mining area based on visual MODFLOW. Environ Earth Sci 77:400–406
Zhang JC, Peng SP (2005) Water inrush and environmental impact of shallow seam mining. Environ Geol 48:1068–1076
Zhang JX, Jiang HQ, Deng XJ, Ju F (2014a) Prediction of the height of the water-conducting zone above the mined panel in solid backfill mining. Mine Water Environ 33:317–326
Zhang W, Zhang DS, Wu LX, Wang HZ (2014b) On-Site radon detection of mining-induced fractures from overlying strata to the surface: a Case study of the Baoshan Coal Mine in China. Energies 7:8483–8507
Zhang DS, Fan GW, Ma LQ, Wang A, Liu YD (2009) Harmony of large-scale underground mining and surface ecological environment protection in desert district—a case study in Shendong mining area, northwest of China. Procedia Earth Planetary Sci 1:1114–1120
Zhang MS, Dang XY (2014) Water resources and environmental problems in arid and semi arid regions—analysis of Yulin energy and chemical base in northern Shaanxi. Science Press, Beijing (in Chinese)
Zhang XM, Yu KJ, Xi JD (2000) The research and application of micro seismic technology in mine fractured and caving zones monitoring. J Chin Coal Soc 25:566–570 (in Chinese)
Zhu WC, Tang CA (2006) Numerical simulation of Brazilian disk rock failure under static and dynamic loading. Int J Rock Mech Min 43:236–252
Acknowledgments
The authors gratefully acknowledge the support provided by the National Key Research and Development Program of China (2017YFC0603004).
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Fan, H., Wang, L., Lu, Y. et al. Height of water-conducting fractured zone in a coal seam overlain by thin bedrock and thick clay layer: a case study from the Sanyuan coal mine in North China. Environ Earth Sci 79, 125 (2020). https://doi.org/10.1007/s12665-020-8873-0
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12665-020-8873-0