材料科学
泥浆
煤矸石
粘度
流变学
复合材料
粒度分布
粒子(生态学)
悬挂(拓扑)
岩土工程
结算(财务)
水泥
泥石流
陶瓷
变形(气象学)
压力(语言学)
固化(化学)
粒径
腐蚀
流量(数学)
凝聚力(化学)
离散元法
磁层粒子运动
残余强度
粒状材料
熔渣(焊接)
应力集中
水煤
表观粘度
断裂(地质)
井漏
剪切减薄
作者
Xiangqian Zhao,Jianbiao Bai,Hao Fu,Gongyuan Wang,Xiangyu Wang,Shuaigang Liu,Rui Wang,Huanyu Liu
标识
DOI:10.1016/j.cscm.2025.e05338
摘要
This study explores the substantial influence of coal gangue particle distribution morphology on the strength of gangue-containing backfill in gob-side entry retaining, while addressing the challenges associated with controlling it. Viscosity testing and CT scanning were conducted to quantify the temporal variations in the solidification viscosity of high-water material (HWM) slurry and the suspension depth of gangue particles. A particle migration equation within HWM slurry was derived for various curing ages, while a settlement coefficient ( S c ) was introduced to characterize the distribution morphology. Then, gangue motion and suspension characteristics were simulated using PFC2D coupled with Fish language scripting. Results indicated that S c increased with release time but decreased with release flow rate, height, and particle size, and a uniform particle distribution ( S c ≈ 1) was found to maximize the backfill strength. Furthermore, analyses of stress distribution, crack propagation, and energy evolution revealed that stress concentration within gangue particles and inadequate inter-particle bonding are responsible for premature failure in the HWM matrix, ultimately resulting in backfill damage. A framework based on GBM, optimized via GWO (Forward algorithm) and NSGA-II (Inverse algorithm), achieved efficient and accurate feedback prediction among backfill strength, S c , and release parameters. These findings provide insights for solid waste utilization and stability control in gob-side entry retaining.
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