Study on rock-breaking behavior of slit charge under air-deck charging structure

doi:10.16265/j.cnki.issn1003-3033.2025.S2.0012

Abstract

Abstract:

In order to optimize the rock-breaking effect of slit charge and control blasting to reduce rock disturbance, a blasting model test was carried out. The test was conducted to blast cylindrical red sandstone under the strip-shaped slit charge frame. The charge sections were set up in three positions: top, middle, and bottom along the axial direction of the air cylinder. After the blasting, CT technology was used, and the damage to the red sandstone after the blasting was quantitatively evaluated based on the fractal dimension theory. The results show that the blasting of the air-deck charge at the top and bottom in the middle of sample B exhibits the optimal controlled blasting effect. Its overall damage degree and porosity are the lowest, and the damage is more concentrated in the direction of the slit of the charge. The fracture morphology is approximately symmetrical, and the expansion is stable. In contrast, the other two both show different degrees of multi-fracture deflection. The analysis of segmented damage shows that the damage degree of the charge section is lower than that of the adjacent sections. The data image is approximately concave, which proves that the blasting energy has an attenuation effect and a local strengthening effect in the axial direction. The synergistic effect of the slit steel pipe and the air deck can effectively guide the blasting energy to be released smoothly along the slit direction, providing the possibility of achieving safe and low-consumption directional rock breaking.

Key words: air-deck charging, slit charge, blasting, computed tomography (CT), fractal dimension, damage

CLC Number:

X936

QIAN Zhaoming, LIU Hougen, REN Yi, ZHENG Bin, GAO Yongtao, ZHOU Yu. Study on rock-breaking behavior of slit charge under air-deck charging structure[J]. China Safety Science Journal, 2025, 35(S2): 21-28.

Figures/Tables 11

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参数	值
扫描电压/kV	160
电流/μA	40
分辨率/μm	37.79
扫描方式	CT螺旋扫描
最大扫描帧数(帧·圈^-1)	1 200
曝光时间/μs	0.4
最小的分辨率/μm	12
图像合并数	2