煤体强度对爆破致裂缝网跨界面扩展的影响规律研究

doi:10.3724/1000-6915.jrme.2025.0771

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摘要构造演化形成的软硬不同煤层渗透性差异显著，探明不同强度煤体及顶板岩层爆破动态响应状态，对爆破参数优化及巷道围岩控制具有重要现实意义。针对不同强度煤体爆破增透效果存在的差异问题，通过模型试验、数值模拟及现场应用相结合的方法研究爆破能量衰减规律、煤岩损伤断裂特征。为定量表征煤体内部的损伤演化过程，引入分形维数对爆破裂隙网络的复杂程度进行量化，并基于Weibull理论和损伤概率密度函数，建立适用于硬煤与软煤的损伤变量与分形维数之间的定量关系，构建基于分形维数的爆破损伤预测模型。结果表明：（1）坚硬煤体爆破裂纹扩展范围广，增透效果好，顶板破坏严重；松软煤体粉碎区大，增透效果差，顶板受扰动小；应变及振动加速度数据分析表明，爆炸应力波由软煤穿过煤岩交界面至岩层时，其应力波衰减程度大于硬煤。（2）损伤演化分析表明，硬煤损伤呈条纹状而软煤呈以炮孔为中心的区域性损伤；通过ImageJ软件计算发现，同一时刻硬煤分形维数大于软煤；所构建的硬煤与软煤损伤预测模型拟合优度分别高达0.96和0.94，证实利用分形维数可定量评估损伤的可靠性。（3）基于试验及数值模拟研究结果，指导赵固二矿硬煤层爆破增透现场的装药参数设计，结果表明，爆破后3 h瓦斯抽采浓度由15.33%提升至36.74%，抽采纯量由0.085 m3/min提升至0.587 m3/min，巷道顶板未出现显著破坏。研究结果可为不同强度煤体爆破增透工程现场的装药设计提供参考和理论依据。

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关键词 ：岩石力学, 爆破增透, 软煤, 硬煤, 爆破应力波, 煤岩损伤

Abstract：The permeability differences between soft and hard coal seams resulting from tectonic evolution are significant. Investigating the dynamic response of coal and roof rock layers with varying strengths during blasting is crucial for optimizing blasting parameters and controlling the surrounding rock in underground roadways. To address the discrepancies in permeability enhancement due to blasting in coals of different strengths, this study employed a combined approach involving model testing, numerical simulation, and field application to examine the attenuation of blasting energy and the damage-fracture characteristics of coal and rock. To quantitatively characterize the damage evolution process within coal, the fractal dimension was introduced to quantify the complexity of the crack network induced by blasting. Based on Weibull theory and the damage probability density function, a quantitative relationship between damage variables and fractal dimension applicable to both hard and soft coal was established, leading to the construction of a blasting damage prediction model based on fractal dimension. The results indicate the following: (1) Blasting in hard coal results in extensive crack propagation, leading to effective permeability enhancement but significant roof damage. In contrast, blasting in soft coal creates a larger crushing zone, resulting in limited permeability enhancement and minimal roof disturbance. Analysis of strain and vibration acceleration data reveals that as the explosive stress wave travels from soft coal across the coal-rock interface into the rock layer, it experiences greater attenuation compared to its travel from hard coal. (2) Damage evolution analysis shows that damage in hard coal appears as striated patterns, while in soft coal, it manifests as regional damage centered around the borehole. Calculations using ImageJ software demonstrate that the fractal dimension of hard coal is greater than that of soft coal at the same time point. The developed damage prediction models for hard and soft coal exhibited high goodness-of-fit, with R² values of 0.96 and 0.94, respectively, confirming the reliability of using fractal dimension for quantitative damage assessment. (3) Based on experimental and numerical simulation results, the charging parameters for blasting permeability enhancement in hard coal seams at Zhaogu No. 2 Mine were designed. Field results indicated that three hours after blasting, the gas drainage concentration increased from 15.33% to 36.74%, and the pure drainage volume rose from 0.085 m³/min to 0.587 m³/min, with no significant damage observed in the roadway roof. These research findings provide a reference and theoretical basis for charge design in blasting permeability enhancement engineering for coals of varying strengths.

Key words： rock mechanics permeability enhancement by blasting soft coal hard coal blasting stress wave coal and rock damage

引用本文:

高魁1，2，3，李点尚1*，任波1，王有为2，曾庆辉1，杨洋1，乔国栋2，张先跃2. 煤体强度对爆破致裂缝网跨界面扩展的影响规律研究[J]. 岩石力学与工程学报, 2026, 45(5): 1392-1408.
GAO Kui1, 2, 3, LI Dianshang1*, REN Bo1, WANG Youwei2, ZENG Qinghui1, . Effect of coal strength on the propagation of blasting-induced crack networks across interfaces. , 2026, 45(5): 1392-1408.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0771 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I5/1392

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