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Hongjian Lu, Chao Mou, Lang Liu, Sheng Li, Yanbo Zhang, Deqing Gan, Youzhi Zhang, Zhiyi Liu, Zhenlin Xue, and Zhiguo Wang, Experimental investigation on mechanical properties of backfill-rock composite structure under in-situ mining and filling stress loading, Int. J. Miner. Metall. Mater., (2026). https://doi.org/10.1007/s12613-025-3322-4
Hongjian Lu, Chao Mou, Lang Liu, Sheng Li, Yanbo Zhang, Deqing Gan, Youzhi Zhang, Zhiyi Liu, Zhenlin Xue, and Zhiguo Wang, Experimental investigation on mechanical properties of backfill-rock composite structure under in-situ mining and filling stress loading, Int. J. Miner. Metall. Mater., (2026). https://doi.org/10.1007/s12613-025-3322-4
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原位采充应力加载下岩–充组合体力学特性试验研究

摘要: 矿床开采与充填过程中,深部岩–充组合体作为采充承载核心结构会受到三向地应力、开挖卸荷及爆破扰动共同作用,呈现复杂的动静组合受力特征。为系统研究原位采充应力加载下组合体的力学特性,开展了真三轴动静组合试验,分析了埋深、灰砂配比及胶结面倾角对组合体强度、变形特征和破坏模式的影响,并结合声发射监测揭示其损伤演化规律。结果表明:随着埋深、灰砂配比及接胶结倾角增大,组合体峰值强度和弹性模量总体呈增加趋势;灰砂配比为1:8时试样表现出明显岩体主导的脆性破坏特征,而灰砂配比为1:4时则表现出充填体与岩体协同承载特征,浅部以延性破坏为主,深部逐渐向脆性破坏转变。声发射活动主要集中于加载–卸荷扰动阶段、塑性屈服阶段及最终破坏阶段,破坏形式以拉–剪复合破坏为主,且剪切裂纹占比随埋深增加而提高。基于声发射能量建立的损伤本构模型能够较好描述组合体从初始损伤、加速损伤到最终失稳破坏的全过程。研究成果可为深部采场充填体灰砂配比优化及稳定性评价提供理论依据。

 

Experimental investigation on mechanical properties of backfill-rock composite structure under in-situ mining and filling stress loading

Abstract: Backfill-rock composite structures (BRCSs) are crucial for the stability of underground mining areas. However, during the mining and backfilling cycles, they are subjected to coupled dynamic-static loading. Herein, to systematically investigate the mechanical properties of BRCSs under in situ mining and filling stress loading, true triaxial dynamic-static tests were conducted. First, the effects of the depth, cement-tailings ratio (C/T), and interfacial angle (IA) on the composite strength, deformation characteristics, and failure modes were systematically investigated. Subsequently, the evolution of acoustic emission (AE) signal parameters during BRCS failure was analyzed. Finally, a damage constitutive model was established based on the AE energy analysis. With increasing depth, C/T ratio, and IA, the peak strength and elastic modulus of the BRCS exhibited an upward trend, and the strain during the loading-unloading disturbance stages correspondingly increased. At a C/T of 1:8, the specimens exhibited a rock-dominated load-carrying capacity with distinct brittle failure. Conversely, at a C/T ratio of 1:4, the specimens demonstrated a coupled backfill-rock load-carrying capacity, exhibiting ductile failure in the shallow regions and a transition to brittle failure in the deeper zones. AE signals were concentrated during loading-unloading disturbance, plastic yielding, and failure stages. The dominant failure mode was tensile-shear composite fracture, with the proportion of shear cracks gradually increasing with depth. The damage evolution process of a BRCS can be divided into three stages: initial, accelerated, and ultimate failures. This study provides an important theoretical basis and practical guidance for optimizing C/T and enhancing stability assessment in backfilled mine designs.

 

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