Study on the Migration Pattern of Concentrated Brine in Underground Concentrated Brine Storage Reservoir: A Case Study in Ling Xin Mining Area

The discharge of mine water from underground coal mines in arid areas is leading to extensive water loss and secondary pollution. To eliminate the water loss and environmental pollution, sealing the concentrated brine after the mine water treatment in the underground storage and pumping the clean wa...

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Bibliographic Details
Published inGeofluids Vol. 2022; pp. 1 - 19
Main Authors Hu, Xiaolong, Li, Xiaolong, Huang, Hui, Song, Xidong, Gao, Jun, Wu, Shaoxue, Kong, Guocai, Duan, Zhiwei
Format Journal Article
LanguageEnglish
Published Chichester Hindawi 26.04.2022
Hindawi Limited
Wiley
Subjects
Analysis
Aquifers
Brines
Case studies
Coal
Coal industry
Coal mines
Coal mining
Construction
Environmental pollution
Environmental risk
Groundwater
Groundwater reservoirs
Leakage
Mine drainage
Mine water
Mine waters
Mineral industry
Mines
Mining industry
Penetration
Permeability
Pollutants
Pollution
Purification
Reservoir storage
Reservoirs
Riparian buffers
Salinity
Simulation
Site selection
Solute transport
Solutes
Storage reservoirs
Surface water
Underground mines
Underground storage
Water
Water discharge
Water loss
Water pollution
Water quality
Water treatment
Water, Underground
China
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Summary:The discharge of mine water from underground coal mines in arid areas is leading to extensive water loss and secondary pollution. To eliminate the water loss and environmental pollution, sealing the concentrated brine after the mine water treatment in the underground storage and pumping the clean water to the surface for recycling are effective methods. In this study, focusing on the Ling Xin mining area, China, a coupled model of concentrated brine flow and solute transport in underground reservoir was established. The migration patterns of concentrated brine under two simulation scenarios of long-term penetration and sudden leakage were analyzed. At the same time, it also initially revealed the essence of the environmental pollution caused by the penetration and leakage of the concentrated brine in the underground concentrated brine storage reservoir. Results show that the concentrated brine would penetrate the bottom aquifer in about 60 years in long-term penetration while approximately 40 days in sudden leakage. In addition, the storage time, reservoir permeability, and groundwater head difference were important factors affecting the migration of concentrated brine, where the influence of permeability varieties was the most significant. The results of this study provide technical options for the subsequent study of the environmental risk of underground concentrated brine reservoirs and have important technical significance for the study and engineering application of underground reservoirs in arid areas.
ISSN:1468-8115
1468-8123
DOI:10.1155/2022/7365519