Numerical study on the fragmentation of rock under single free face explosion of variable diameter decoupled charge.

IF 3.8 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-04-08 DOI:10.1038/s41598-025-96636-w

Jiabing Lyu, Tiejun Tao, Caijin Xie

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Abstract

In the conventional radial uncoupled charge single free surface blasting, the bottom rock mass is difficult to be fully broken, which affects the blasting effect and restricts the tunneling efficiency. This difficulty adversely impacts the blasting outcome and limits the efficiency of excavation. To address this issue, this paper proposes a solution that involves modifying the charge structure to implement a variable diameter decoupled charge, and it analyzes the theoretical feasibility of this approach. The variably diameter decoupled charge and radial decoupled charge single-hole blasting model was established and compared using LS-DYNA. Furthermore, the effects of various parameters on the rock-breaking efficiency of variable diameter decoupled charges were analyzed. The results show that, in comparison to radially decoupled charges, variable diameter decoupled charges exhibit a greater explosive mass at their base. This enhancement leads to an increase in the effective stress on the surrounding rock, thereby effectively addressing the issue of inadequate fragmentation of the rock mass at the base of radially decoupled charges. Simultaneously, the directional effect of stress wave superposition and the balancing effect of the cavity on internal pressure contribute to an increase in the effective stress and reflected tensile stress of the overlying rock mass. This phenomenon ensures that effective fragmentation of the overlying rock mass can still be achieved, even with a relatively small amount of explosive charge. Under the condition of maintaining the same charge weight and borehole diameter, increasing the length and radius of the expanding section of the explosive significantly impacts rock fragmentation, whereas reducing the radius of the contracting section has a minimal effect. In engineering applications with a common borehole diameter of 4.2 cm, when the length of the expanding section of the explosive charge is half of the total charge length and the radius of the expanding section ranges from 1.65 cm to 1.70 cm, more effective rock fragmentation at the bottom can be achieved, resulting in an overall favorable fragmentation outcome.

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变直径解耦装药单自由面爆炸破碎岩石的数值研究。

传统的径向不耦合装药单自由面爆破，由于底部岩体难以完全破碎，影响了爆破效果，制约了掘进效率。这一困难影响了爆破效果，限制了开挖效率。针对这一问题，本文提出了一种通过改变电荷结构实现变直径解耦电荷的解决方案，并分析了该方法的理论可行性。利用LS-DYNA建立变直径解耦装药和径向解耦装药单孔爆破模型，并进行了比较。进一步分析了不同参数对变直径解耦装药破岩效率的影响。结果表明，与径向解耦电荷相比，变直径解耦电荷在其底部表现出更大的爆炸质量。这种增强导致了围岩有效应力的增加，从而有效地解决了径向解耦装药基础处岩体破碎不足的问题。同时，应力波叠加的方向性作用和空腔对内压的平衡作用使上覆岩体的有效应力和反射拉应力增大。这种现象确保了即使使用相对少量的炸药，也能有效地破碎上覆岩体。在保持装药量和钻孔直径相同的情况下，增大炸药膨胀段长度和半径对破岩影响显著，减小收缩段半径影响较小。在常见钻孔直径为4.2 cm的工程应用中，当爆药膨胀段长度为总装药长度的一半，膨胀段半径在1.65 cm ~ 1.70 cm范围内时，可以实现更有效的底部破岩，整体破岩效果较好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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