Authors: Morgan, H; Hocking, A; Henderson, S

Open access courtesy of:

DOI https://doi.org/10.36487/ACG_rep/1915_105_Morgan

Cite As:
Morgan, H, Hocking, A & Henderson, S 2019, 'Simplified method to predict final void water levels', in AB Fourie & M Tibbett (eds), Mine Closure 2019: Proceedings of the 13th International Conference on Mine Closure, Australian Centre for Geomechanics, Perth, pp. 1337-1352, https://doi.org/10.36487/ACG_rep/1915_105_Morgan

Download citation as:   ris   bibtex   endnote   text   Zotero


Abstract:
At the completion of open cut coal mining, the open cut pit may remain, becoming a final void. In the majority of cases, the BHP final voids will collect water until they reach an equilibrium level where net inflows equal net outflows. BHP currently has over 100 open cut coal mine pits across Queensland and New South Wales coal operations, some of which may be final voids at closure. A decision framework is being developed by BHP to facilitate more efficient and consistent decisions about rehabilitation of final voids. Within this framework, an understanding of the pit lake equilibrium water level is needed to assess the interaction with groundwater aquifers (whether the void will be a groundwater sink or a source of groundwater recharge) and the likelihood of discharges (overflowing) to surface waters. At present, the most common method for predicting the final void pit lake level is to use a daily time step water balance model (WBM), often derived from complex WBMs developed for site operations. Considering the number of pits BHP needs to assess at various stages of mine planning, with frequent mine plan changes in the decades prior to closure, developing and continuously updating complex WBMs for each pit would result in inefficient closure planning. Consequently, BHP recognised the benefit in developing a simple and efficient screening method to predict the long-term pit lake water level. To facilitate the development, a suite of daily time step WBMs were developed based on the current methodology BHP adopts to assess final voids. The aim of the WBMs was to evaluate the typical behaviour of the pit lake using a range of representative final void configurations from a representative sample of seven BHP operations. Recognising the uncertainty in the key parameters adopted in the BHP operational WBMs, a sensitivity analyses of four key parameters associated with runoff, evaporation, groundwater and spoil storage were undertaken. The results were used to guide the development of the screening method by identifying which parameters have the most influence and should therefore be accounted for in predicting the behaviour of pit lakes. A ‘pit lake prediction tool’ has been developed and benchmarked to the WBM results to show confidence in the screening method. A risk assessment was included to allow effective communication of the pit lakes’ risk of interacting with groundwater or spilling to the receiving environment. This pit lake prediction tool forms part of the BHP final void decision framework, which facilitates more efficient and consistent decisions about rehabilitation of final voids.

Keywords: water balance model, final voids, mine closure, pit lake

References:
Ball, J, Babister, M, Nathan, R, Weeks, W, Weinmann, E, Retallick, M & Testoni, I, 2016, Australian Rainfall and Runoff (ARR): A Guide to Flood Estimation, Commonwealth of Australia.
Boughton, WC 2004, ‘The Australian Water Balance Model’, Environmental Modelling and Software, October 2004, vol. 19, iss. 10, pp. 943‒956.
Calder, IR & Neal, C 1984, ‘Evaporation from saline lakes: a combination equation approach’, Hydrological Sciences Journal, vol. 29, pp. 89‒97.
Commonwealth Scientific and Industrial Research Organisation (CSIRO) 2015, ‘Climate Change in Australia’, Information for Australia’s Natural Resource Management Regions: Technical Report, CSIRO and Bureau of Meteorology.
GoldSim 2017, GoldSim Version 12 User’s Guide Volume 1 & 2, GoldSim Technology Group, Issaquah.
Hawkins, JW 2004, ‘Some hydrologic properties of surface mine spoil in the Appalachian plateau’, Proceedings America Society of Mining and Reclamation, pp. 860‒878.
Hydro Engineering & Consulting Pty Ltd (HEC) 2018, BHP Open Cut Coal Mines Final Void Water Balance, Sep 2018.
McJannet, D, Hawdon, A, Van Niel, T, Boadle, D, Baker, B, Trefry, M & Rea, I 2017, ‘Measurements of evaporation from a mine void lake and testing of modelling approaches’, Journal of Hydrology, vol. 555, pp. 631‒647,
Mulder, JC 1997, Queensland Lake and Aerial Evaporation, Volume 1, Report 000302.PR/2, Department of Natural Resources, Brisbane.
The Department of Environment and Science (DES) 2018, SILO climate data, viewed June/July 2018,
Worley Parsons 2013, ‘North Star Mine pit lake assessment, water and solute modelling’, Water Solutions, Perth.




© Copyright 2024, Australian Centre for Geomechanics (ACG), The University of Western Australia. All rights reserved.
View copyright/legal information
Please direct any queries or error reports to repository-acg@uwa.edu.au