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Wei He, Lang Liu, Tiantian Li, Ruofan Wang, Huisheng Qu, Chengcheng Shao, Zihan Wang, and Qing Wang, Investigation of backfill creep characteristics under different stress levels and initial bearing ages and their effects on strength and permeability, Int. J. Miner. Metall. Mater., (2026). https://doi.org/10.1007/s12613-025-3351-z
Wei He, Lang Liu, Tiantian Li, Ruofan Wang, Huisheng Qu, Chengcheng Shao, Zihan Wang, and Qing Wang, Investigation of backfill creep characteristics under different stress levels and initial bearing ages and their effects on strength and permeability, Int. J. Miner. Metall. Mater., (2026). https://doi.org/10.1007/s12613-025-3351-z
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不同应力水平与初始承载龄期下充填体的蠕变特性及其对强度和渗透性能的影响

摘要: 充填体初始承载龄期主要受顶板垮落时长控制,该指标对充填体水化阶段力学及渗透性能起到决定性作用。本次研究开展时长96 h单轴压缩蠕变与渗透试验,探究不同应力水平、不同初始承载龄期双重条件下,胶结充填体蠕变演化规律,以及蠕变作用对充填体强度、渗透特性的影响规律。试验结果显示:提升外部应力水平后,28 d龄期充填体累积轴向应变由0.962%升至1.647%。延长充填体初始承载龄期,蠕变减速阶段轴向应变曲线形态逐步由凹形转变为凸形。与此同时,充填体蠕变减速阶段应变速率曲线呈锯齿波动特征,该阶段蠕变时长随龄期增长大幅缩短,3 d龄期对应蠕变时长为15~25 h,28 d龄期则缩减至0~10 h。蠕变试验完成后,各组充填体试样表面均未出现直观的宏观裂缝,但试样抗压强度、渗透率参数存在明显差异性。静荷载作用可有效加固3 d早期充填体,试样抗压强度提升19.95%,渗透系数同步下降30.90%;反观28 d后期充填体,静荷载会对基体产生不可逆结构性损伤,致使充填体抗压强度衰减31%,渗透率大幅升高116.29%。综上可知,应力水平与初始承载龄期两大参数,会显著调控静载工况下胶结充填体的力学及渗透性能。本次研究结论能够为井下充填工程现场安全管控、充填体强度参数优化设计,提供理论依据与工程实操参考。

 

Investigation of backfill creep characteristics under different stress levels and initial bearing ages and their effects on strength and permeability

Abstract: The initial bearing age of a backfill is primarily determined by the roof collapse time, which critically affects its performance during the hydration stage. In this study, 96 h uniaxial compression creep and permeability tests were conducted to investigate the creep behavior of cemented backfill at different stress levels and initial bearing ages and their effects on strength and permeability. The results indicated that with an increase in the stress level, the cumulative axial strain of 28 d backfill increases from 0.962% to 1.647%. As the initial bearing age of the backfill increased, the axial strain curve in the creep deceleration stage gradually changed from concave to convex. Simultaneously, the strain rate curve of the backfill in the creep deceleration stage was characterized by a sawtooth-like fluctuation, and the creep time in this interval was shortened from 15 ‒ 25 (3 d) to 0 ‒ 10 h (28 d). Additionally, there were no evident macroscopic cracks on the surface of the backfill after the creep test, but its compressive strength and permeability exhibited significant differences. Static load exerted a significant strengthening effect on the 3-d-old backfill, with its compressive strength index increased by 19.95%, while the permeability index decreased by 30.90%. In contrast, static load caused damage to the backfill on the 28 d, leading to 31% decrease in compressive strength and 116.29% increase in permeability. Therefore, the stress level and initial load-bearing age had a significant impact on the mechanical properties of the backfill under static load. These findings provide valuable insights and practical references for on-site safety applications and strength design of backfills.

 

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