尾矿
岩土工程
凝聚力(化学)
抽吸
饱和(图论)
排水
采矿工程
地质学
环境科学
工程类
材料科学
冶金
机械工程
生态学
化学
数学
有机化学
组合数学
生物
作者
Yue Zhao,Abbas Taheri,Lei Guo,Murat Karakus,An Deng
标识
DOI:10.56952/arma-2022-0667
摘要
ABSTRACT: Backfilling has increasingly been used to fill the mined cavities in underground mine operations, to reuse tailings in underground mines. Influence factors of mine backfills’ mechanical performance have been widely studied over the past few decades to minimize operating costs and superior mechanical support for underground exploration. However, additional work is required to consider more realistic conditions of in-situ backfill stope, such as the drainage of initially saturated backfill and the interference of surrounding underground water, which may lead to the variation of backfill stope saturation condition. A series of triaxial compression tests under various confining pressures for compacted backfill samples were carried out at designed matric suction values (0kPa, 50 kPa, 200 kPa, 400 kPa, and 600 kPa) to predict the influence of post-desiccation and post-saturation on in-situ backfill stope. Overall, with the increase of matric suction, the unsaturated specimens were found to have a higher peak deviator stress than saturated specimens for any given confining pressure and thus led to improved mechanical performance. The cohesion and friction angles show a linear relationship concerning the matric suction. 1. INTRODUCTION Mine tailings, deposited after minerals have been extracted, are the largest source of waste in mine processing. Approximately 14 billion tons of tailings were produced globally by the mining industry in 2010 (Behera et al. 2021; Jones and Boger 2012; Naganathan et al. 2012; Zhao et al. 2018). Tailings have been traditionally deposited into tailings storage facilities associated with severe environmental, geotechnical, and economic concerns (Dold 2014; Franks et al. 2011; Liu et al. 2016). Backfill technology has increasingly been used to fill the mined cavities in underground mine operations to reuse tailings in underground mines (Fall et al. 2010; Sivakugan et al. 2006; Zhang et al. 2012). Backfill material generally consists of tailings, none or a low proportion of cementitious binders to form a high-density slurry with none setting character to be gravity transferred or pumped to underground mine voids. Backfill recycles processed tailings into underground mined voids, which reduces the volume that needs to be surface-disposed. Using backfill thus mitigates the potential environmental impacts associated with tailings disposal and assists waste management (Fall et al. 2010; Kesimal et al. 2004; Tang et al. 2021; Zhao et al. 2021). These refilled backfills can then perform as both the support system and working platform for further ore extraction (Grabinsky et al. 2021; Ouattara et al. 2017; Sivakugan et al. 2015). Over the past few decades, backfill technology has been increasingly applied to revive mined cavities in underground mine operations, owing to its low operating costs as well as its superior mechanical performance compared with other backfilling methods (Fall and Pokharel 2010; Xu et al. 2018; Zhao et al. 2019).
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