静压和爆破耦合作用下岩石断裂和破碎的实验和数值研究

IF 4.7 2区 工程技术 Q1 MECHANICS
Kewei Liu , Xudong Li , Jiacai Yang , Zilong Zhou , Yanyan Sha , Zhixian Hong
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引用次数: 0

摘要

爆破技术在土木工程和采矿工程中被广泛用于破碎岩石,其操作一般受到构造应力和重力的静压作用。本研究对静压(单轴压力和约束压力)和爆破耦合作用下的岩石断裂和破碎进行了实验和数值研究。首先,基于双轴加载系统,对 100 毫米立方体红砂岩样本进行了 11 次爆破试验。然后,使用 LS-DYNA 有限元方法对爆破试验中产生的岩石破碎进行了数值建模,并对岩石样本中的爆炸压力衰减和断裂演化进行了数值再现。利用 ImageJ 软件对模拟岩石破碎数据进行图像处理,并利用 Weibull 分布表征了红砂岩在静应力和爆破共同作用下的破碎粒度分布。据此,定量比较和分析了单轴压力和约束压力对爆破产生的岩石破碎的影响,并讨论和揭示了相应的机理。目前的研究结果表明,静压在径向和环向都起到了增加爆破引起的压应力和减少拉应力的作用,从而导致垂直于施加压力方向的裂缝长度和数量减少,进一步导致产生更粗的破碎。与单轴压力下的爆破相比,约束压力下的爆破产生的碎片更大。随着静应力的增加,平均碎片尺寸开始迅速增大,然后缓慢增大,这可以用对数方程很好地描述。根据目前的研究结果,在实际爆破中,增加自由表面对于提高爆破下的岩石破碎性能至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental and numerical investigation on rock fracturing and fragmentation under coupled static pressure and blasting
The blasting technique is widely adopted to break rock in civil and mining engineering, and its operation is generally subjected to static pressure due to tectonic and gravitational stresses. In the present study, the rock fracturing and fragmentation under coupled static pressure (uniaxial pressure and confining pressure) and blasting are experimentally and numerically investigated. First, 11 blast tests with 100-mm cubic red sandstone samples are carried out based on a biaxial loading system. Then, the blast-produced rock fragmentation in blast testing is numerically modeled using finite element method with LS-DYNA, and the explosion pressure attenuation and fracture evolution in rock samples are numerically reproduced. The simulated rock fragmentation data are obtained by image processing in ImageJ, and the fragment size distribution of red sandstone under combined static stress and blasting is characterized using Weibull distribution. Accordingly, the effects of uniaxial pressure and confining pressure on blast-created rock fragmentation are quantitatively compared and analyzed, and the corresponding mechanisms are discussed and revealed. The current findings indicate that the static pressure plays a role in increasing blast-induced compressive stress and reducing tensile stress in both radial and hoop directions and thus results in a decrease in the length and number of fractures propagating vertically to the direction of applied pressure, further leading to the creation of coarser fragmentation. Blasting under confining pressure produces larger fragments than that under uniaxial pressure. The average fragment size increases quickly at first and then increases slowly with the increase of static stress, which can be well characterized using a logarithm equation. Based on current findings, increasing the free surface is crucial in practical blasting to improve rock fragmentation performance under blasting.
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来源期刊
CiteScore
8.70
自引率
13.00%
发文量
606
审稿时长
74 days
期刊介绍: EFM covers a broad range of topics in fracture mechanics to be of interest and use to both researchers and practitioners. Contributions are welcome which address the fracture behavior of conventional engineering material systems as well as newly emerging material systems. Contributions on developments in the areas of mechanics and materials science strongly related to fracture mechanics are also welcome. Papers on fatigue are welcome if they treat the fatigue process using the methods of fracture mechanics.
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