Abstract
The hydrogeological conditions of coal mines in China are quite complex, and water inrush accidents occur frequently with disastrous consequences during coal extraction. Among them, the risk of coal mining under a river is the highest due to the high water transmissivity and lateral charge capacity of the unconfined aquifer under the river. The danger of mining under a river requires the accurate determination of the developmental mechanisms of the water flowing fractured zone (WFFZ) and the water flow mechanisms influenced by the specific geological conditions of a coal mine. This paper first used the transient electromagnetic (TEM) method to monitor the development of the WFFZ and the water flow mechanisms following the mining of a longwall face under a river. The TEM survey results showed that the middle Jurassic coarse sandstone aquifer and the Klzh unconfined aquifer were the main aquifers of the 8101 longwall panel, and the WFFZ reached the aquifers during the mining process. Due to the limited water reserves in the dry season, the downward flowing water mainly came from the lateral recharge in the aquifer. The water inrush mechanisms of the 8101 longwall panel in Selian No.1 Coal mine were analyzed based on the water flow mechanisms of the aquifer and the numerical simulation results. This provides theoretical and technical guidance to enact safety measures for mining beneath aquifers.
Highlights
The hydrogeological conditions of coal mines in China are quite complex, and water-bearing bodies exist in coal mines
Cannot reach the aquifer according to the empirical formula
The 2D numerical and the transient electromagnetic (TEM) survey showed that the water quickly flowed down when the water flowing fractured zone (WFFZ) connected to the overlying aquifer, which is consistent with the literature [29]
Summary
The hydrogeological conditions of coal mines in China are quite complex, and water-bearing bodies exist in coal mines. Water inrush accidents cause a huge number of casualties and economic losses and seriously affect the normal production of the coal mine. Water inrush accidents occur mostly as roof water inrush during extraction. The water flowing fractured zone (WFFZ) is composed of the lower two zones, in which mining-induced fractures are relatively developed. The connection between the mining-induced fractures of the longwall face and the overlying water-bearing bodies results in a strong water-conducting channel, through which the water from the overlying aquifer flows downward into the longwall face and causes a water inrush accident. It is necessary to determine the developmental mechanisms of a WFFZ and the water flow mechanisms during the mining process to guide the safe extraction of a longwall face
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