Forecasting of water yield of deep-buried iron mine in Yanzhou, Shandong

WANG Ye; ZHANG Qiu-lan; WANG Shi-chang; SHAO Jing-li

Volume 3 Issue 4

Dec. 2015

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Article Navigation > Journal of Groundwater Science and Engineering > 2015 > 3(4): 342-350

WANG Ye, ZHANG Qiu-lan, WANG Shi-chang, et al. 2015: Forecasting of water yield of deep-buried iron mine in Yanzhou, Shandong. Journal of Groundwater Science and Engineering, 3(4): 342-350.

Citation:

WANG Ye, ZHANG Qiu-lan, WANG Shi-chang, et al. 2015: Forecasting of water yield of deep-buried iron mine in Yanzhou, Shandong. Journal of Groundwater Science and Engineering, 3(4): 342-350.

WANG Ye, ZHANG Qiu-lan, WANG Shi-chang, et al. 2015: Forecasting of water yield of deep-buried iron mine in Yanzhou, Shandong. Journal of Groundwater Science and Engineering, 3(4): 342-350.

Citation:

WANG Ye, ZHANG Qiu-lan, WANG Shi-chang, et al. 2015: Forecasting of water yield of deep-buried iron mine in Yanzhou, Shandong. Journal of Groundwater Science and Engineering, 3(4): 342-350.

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Forecasting of water yield of deep-buried iron mine in Yanzhou, Shandong

1School of Water Resources and Environment, China University of Geosciences, Beijing 100083, China.2Shangdong Institute of Geophysical & Geochemical Exploration, Jinan 250013, China.

Publish Date: 2015-12-28

Abstract

Abstract

This paper compares analytical and numerical methods by taking the forecasting of water yield of deep-buried iron mine in Yanzhou, Shandong as an example. Regarding the analytical method, the equation of infinite and bilateral water inflow boundary is used to forecast the water yield, and in the case of numerical simulation, we employed the GMS software to establish a model and further to forecast the water yield. On the one hand, through applying the analytical method, the maximum water yield of mine 1 500 m deep below the surface was calculated to be 13 645.17 m3/d; on the other hand, through adopting the numerical method, we obtained the predicted result of 3 816.16 m3/d. Meanwhile, by using the boundary generalization in the above-mentioned two methods, and through a comparative analysis of the actual hydro-geological conditions in this deep-buried mine, which also concerns the advantages and disadvantages of the two methods respectively, this paper draws the conclusion that the analytical method is only applicable in ideal conditions, but numerical method is eligible to be used in complex hydro-geological conditions. Therefore, it is more applicable to employ the numerical method to forecast water yield of deep-buried iron mine in Yanzhou, Shandong
- Analytical method,
- Numerical simulation,
- Forecasting of water yield,
- Yanzhou deep-buried iron mine

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References(14)

References

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