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Abstract
Thar coalfield is a new coalfield in Pakistan with estimated lignite resource of more than 175 billion tons. Resource planning is an essential part of the strategic plan for optimal and economical exploitation of Thar lignite. Main objective of the present research is to assess Thar coalfield as a single deposit and identify the areas suitable for surface mining, underground mining and waste dump at Thar coalfield. The cumulative stripping ratio distribution map has been developed for Thar coalfield, covering an area of 1691.04 km2 around 12 exploratory blocks. Lithological data of 693 drill holes have been used to calculate the cumulative stripping ratio in every borehole, which varies from 3.7 m:m to 88.1 m:m with an average value of 12.85 m:m. Cumulative stripping ratio is divided into six ranges, viz: 4–6, 6–8, 8–10, 10–15, 15–20 and >20 m:m. Contours are digitized around all boreholes showing various ranges of stripping ratios. From the cumulative stripping ratio distribution map, it is concluded that 665.72 km2 area, which constitutes 39.37% of the total assessed area, is suitable for surface mining and 989.82 km2 area, constituting 58.53%, is appropriate for underground mining and outside waste dumps. Whereas, 2.1% area is no coal zone, only suitable for outside waste dumping. The developed map of cumulative stripping ratio distribution may be used as a guide map for the preparation of mining master plan for Thar coalfield.
Keywords
openpit
/
stripping ratio
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Surpac
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sustainable development
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Thar coalfield
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Fahad Irfan Siddiqui, Abdul Ghani Pathan, Bahtiyar Ünver, Güneş Ertunç.
Sustainable lignite resource planning at Thar coalfield, Pakistan.
Journal of Central South University, 2018, 25(5): 1165-1172 DOI:10.1007/s11771-018-3815-7
| [1] |
HDIP. Pakistan energy yearbook [M]. Islamabad: Ministry of Petroleum and Natural Resourses, Pakistan, 2012.
|
| [2] |
EIA. International energy outlook: vol. DOE/EIA-0484(2013). [M]. Washington, DC, 2013: 300.
|
| [3] |
RoumposC, PavloudakisF. Modelling and evaluation of open-pit lignite mines exploitation strategy [C]. The 2nd International Conference on Sustainable Development, 2005
|
| [4] |
BowenB H, CanchiD, LalitV A, PreckelP V, SparrowF T, IrwinM W. Planning India's long-term energy shipment infrastructures for electricity and coal [J]. Energy Policy, 2010, 38: 432-444
|
| [5] |
ChikkaturA P, SagarA D, SankarT L. Sustainable development of the Indian coal sector [J]. Energy, 2009, 34: 942-953
|
| [6] |
DanicicD, MitrovicS, PavlovicV, KovacevS. Sustainable development of lignite production on open cast mines in Serbia [J]. Mining Science and Technology (China), 2009, 19(5): 679-683
|
| [7] |
EdigerV S, BerkI, KösebalabanA. Lignite resources of Turkey: Geology, reserves, and exploration history [J]. International Journal of Coal Geology, 2014, 132: 13-22
|
| [8] |
EROL, KilkisB. An energy source policy assessment using analytical hierarchy process [J]. Energy Conversion and Management, 2012, 63: 245-252
|
| [9] |
JovancicP, TanasijevicM, IvezicD. Serbian energy development based on lignite production [J]. Energy Policy, 2011, 39: 1191-1199
|
| [10] |
KaldellisJ K, ZafirakisD, KondiliE. Contribution of lignite in the Greek electricity generation: Review and future prospects [J]. Fuel, 2009, 88: 475-489
|
| [11] |
KavouridisK. Lignite industry in Greece within a world context: Mining, energy supply and environment [J]. Energy Policy, 2008, 36: 1257-1272
|
| [12] |
MathurR, CHANDS, TezukaT. Optimal use of coal for power generation in India [J]. Energy Policy, 2003, 31: 319-331
|
| [13] |
Osman YilmazA, UsluT. Energy policies of Turkey during the period 1923–2003 [J]. Energy Policy, 2007, 35: 258-264
|
| [14] |
PahleM. Germany’s dash for coal: Exploring drivers and factors [J]. Energy Policy, 2010, 38: 3431-3442
|
| [15] |
LiaoX, LiW, HouJ. Application of GIS based ecological vulnerability evaluation in environmental impact assessment of master plan of coal mining area [C]. International Symposium on Environmental Science and Technology, 2013271276
|
| [16] |
SutcuE C. Use of GIS to discover potential coalfields in Yatagan–Milas area in Turkey [J]. International Journal of Coal Geology, 2012, 98: 95-109
|
| [17] |
ÜnverB, TercanA E, HindistanM A, ErtuncG, AtalayF, ÜnalS, KilligluY. Lignite resource estimation of Karapinar-Aazyranc [R]. Mine Modeling and Design Team, 2014
|
| [18] |
PathanA G, SinghR N, StaceR. Geotechnical assessment of block VIII at Thar coalfield, Pakistan [C]. The 23rd World Mining Congress, 2013
|
| [19] |
SinghR N, AtkinsA S, PathanA G. Determination of ground water quality associated with lignite mining in arid climate [J]. International Journal of Mining and Environmental Issues, 2010, 1: 65-78
|
| [20] |
SinghR N, AtkinsA S, PathanA G. Water resources assessment associated with lignite operations in Thar, Sindh, Pakistan [J]. Archives Mining Sciences, 2010, 55: 425-440
|
| [21] |
FassettJ E, DurraniN A. Geology and coal resources of the Thar coal field, Sindh Province, Pakistan [R]. US Geological Survey Open File Report, 1994
|
| [22] |
ThomasR E, ShahA A, KhanS A, TgarM A. Analytical results on coal samples collected from drilling activities in the Thar Desert, Sindh, Pakistan [R]. US Geological Survey Open File Report, 1994
|
| [23] |
GSP. Coal resources of four blocks in Thar coalfield, Sindh, Pakistan: vol. 115 [M]. Geological Survey of Pakistan, 2002: 114.
|
| [24] |
SiddiquiF I, PathanA G, ÜnverB, TercanA E, HindistanM A, ErtuncG, AtalayF, ÜnalS, KilligluY. Lignite resource estimations and seam modeling of Thar Field, Pakistan [J]. International Journal of Coal Geology, 2014, 140: 84-96
|
