Mathematical modelling and simulation for hydrating backfill body under cemented paste backfill/rock interface loading

IF 2.7 3区工程技术 Q3 ENVIRONMENTAL SCIENCES

International Journal of Mining Reclamation and Environment Pub Date : 2022-11-09 DOI:10.1080/17480930.2022.2142423

K. Fang, Jixiong Zhang, L. Cui, Luwei Ding, Xiangqian Xu, W. Timms

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引用次数: 3

Abstract

ABSTRACT Cemented paste backfill (CPB)/rock interface shear resistance results in a spatiotemporal stress reduction in CPB and thus affects the mechanical stability of CPB structure in underground excavations. To study the stress distribution in CPB structure, an integrated model consisting of a cohesive zone model for CPB/rock interface behavior and a multiphysics model for hydrating CPB behavior is developed. The predictability of the proposed model is validated against measurements from laboratory tests and field studies. Thereafter, the validated model is used to investigate the influence of curing time, stope geometry, and field backfilling operation on the spatiotemporal stress development in CPB structure. It has been found that the CPB/rock interface loading is able to reduce the stress levels in CPB by up to 75%, and taking advantage of this phenomenon can significantly reduce the operation cost. Moreover, there exists a critical stope width that governs the extent of stress reduction in CPB. In addition, continuous mining activity in the secondary stope exerts limited impact on the stress redistribution in the primary backfill body. These findings provide practical guidance for the safe design of a CPB structure as well as a more strategic mining plan for the adjacent ore body.

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胶结膏体/岩石界面加载下水化充填体的数学建模与仿真

摘要水泥浆体回填（CPB）/岩石界面抗剪性能导致CPB的时空应力降低，从而影响地下开挖中CPB结构的力学稳定性。为了研究CPB结构中的应力分布，建立了一个由CPB/岩石界面行为的粘性区模型和CPB水化行为的多物理模型组成的综合模型。根据实验室测试和现场研究的测量结果，验证了所提出模型的可预测性。然后，使用验证的模型研究了固化时间、采场几何形状和现场回填操作对CPB结构时空应力发展的影响。研究发现，CPB/岩石界面加载能够将CPB中的应力水平降低75%，利用这一现象可以显著降低操作成本。此外，存在一个临界采场宽度，该宽度决定了CPB中应力降低的程度。此外，二次采场的连续开采活动对一次充填体的应力再分配影响有限。这些发现为CPB结构的安全设计以及相邻矿体的更具战略性的开采计划提供了实际指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Mining Reclamation and Environment ENVIRONMENTAL SCIENCES-MINING & MINERAL PROCESSING

CiteScore

5.70

自引率

8.30%

发文量

审稿时长

>12 weeks

期刊介绍： The International Journal of Mining, Reclamation and Environment published research on mining and environmental technology engineering relating to metalliferous deposits, coal, oil sands, and industrial minerals. We welcome environmental mining research papers that explore: -Mining environmental impact assessment and permitting- Mining and processing technologies- Mining waste management and waste minimization practices in mining- Mine site closure- Mining decommissioning and reclamation- Acid mine drainage. The International Journal of Mining, Reclamation and Environment welcomes mining research papers that explore: -Design of surface and underground mines (economics, geotechnical, production scheduling, ventilation)- Mine planning and optimization- Mining geostatics- Mine drilling and blasting technologies- Mining material handling systems- Mine equipment