Compression-induced saturation in coal mine spoil piles

Fityus, S.; Robertson, H.; Simmons, J.

Title: Compression-induced saturation in coal mine spoil piles
Creator: Fityus, S.; Robertson, H.; Simmons, J.
Relation: 6th International Conference on Unsaturated Soils (UNSAT 2014). Unsaturated Soils: Research & Applications: Proceedings of the 6th International Conference on Unsaturated Soils, Volume 2 (Sydney 2-4 July, 2014) p. 1515-1520
Publisher Link: http://dx.doi.org/10.1201/b17034-221
Publisher: Taylor & Francis
Resource Type: conference paper
Date: 2014
Description: Coal mining produces large quantities of waste rock (spoil) of generally sedimentary origin. Current practice involves stacking this spoil in piles up to 150 m high. Plans for future mining are considering spoil piles up to 400 m high. Under the corresponding burial stresses, the spoil materials undergo substantial compressions, leading to decreases in void ratio and increases in their degree of saturation (S_r) at constant water content. In this study, a typical spoil derived from Permian-aged sandstones and mudrocks, is subjected to stresses up to 20 MPa, with the corresponding changes in degree of saturation and suction measured. The results show that loose spoil with a water content of around 12% (S_r=25%) will collapse to become saturated under a stress of 7 MPa. In contrast, loose spoil with a higher water content of around 16% will collapse to become saturated under a stress of only 1.5 MPa. From these results, a phenomenon is identified whereby spoil in the seepage and capillary zones at the base of very high spoil piles can collapse to a state of saturation. A discussion is provided on the consequences of this for the matric suction and unsaturated shear strength of these spoil materials, which constitute the foundation layer of the pile.
Subject: coal mining; spoil piles; waste dumps
Identifier: http://hdl.handle.net/1959.13/1065535
Identifier: uon:17865
Identifier: ISBN:9781138026902
Language: eng
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