Simulation Study on Energy Distribution of Uncoupled Medium Charge Blasting in High Cold Regions
Received date: 2024-03-26
Revised date: 2024-06-27
Online published: 2024-12-20
With the increasing trend of deep resource mining in China’s alpine regions,the issue of suboptimal outcomes following charge blasting with various coupling medium frequently arises.To investigate the energy distribution of explosives in these alpine environments,and in alignment with the principles of precision blasting,this study first analyzed the explosion pressure transfer characteristics of different coupling media charges based on explosion dynamics theory.Subsequently,using LS-DYNA finite element software,a single-hole decoupling charge blasting funnel model for air,water,and ice was established.Secondly,based on the explosion damage cloud map,the volume of the blasting funnel for the uncoupled medium charge was determined.The attenuation characteristics of the explosion pressure and the energy absorption by the rock mass were subsequently analyzed.Finally,an optimization scheme was proposed based on the research findings and was implemented in on-site blasting operations.The results indicate that,under identical coupling coefficients,the initial pressure peak at the hole wall for water medium decoupling charge blasting increases by a factor of 1.14 to 2.60 compared to air decoupling charge blasting.Additionally,the radius of the blasting funnel crushing zone expands by a factor of 1.04 to 1.11,and the radius of the fracture zone enlarges by a factor of 1.19 to 1.48.For ice medium decoupling charge blasting,the radius of the blasting funnel crushing zone increases by a factor of 1.02 to 1.12,and the radius of the fracture zone expands by a factor of 1.15 to 1.48.The explosion pressure of uncoupled charge in air,water and ice media has an exponential relationship with the distance from the explosion center,when the coupling medium is water medium.
Changchun JIANG , Yi YAO , Yu BAI , Yiqing LI , Yachun MAO . Simulation Study on Energy Distribution of Uncoupled Medium Charge Blasting in High Cold Regions[J]. Gold Science and Technology, 2024 , 32(6) : 1077 -1089 . DOI: 10.11872/j.issn.1005-2518.2024.06.083
| Besson D Z, Kravchenko I, Nivedita K,2023.Polarization angle dependence of vertically propagating radio-frequency signals in South Polar ice[J].Astroparticle Physics,144:102766. | |
| Fei Honglu, Li Shouju, He Qingzhi,1992.Determintion of decouple coefficient and analysis of decouple action in the smooth blasting[J].Explosion and Shock Waves,(3):270-274. | |
| Fei Honglu, Zhen Shuai, Li Wenyan,et al,2022.Coupling analysis of temperature and water field of blast hole for multi-year water-bearing frozen rock burst in plateau[J].Blasting,39(4):32-43. | |
| Henrych J, Major R,1979.The Dynamics of Explosion and Its Use[M].Amsterdam:Elsevier. | |
| Huang Ruibin,2021.Numerical Experimental Study on Water Coupling Effect of Open-Pit Deep-Hole Presplitting Blasting[D].Chengdu:Southwest Jiaotong University. | |
| Jia Z Z, Li H J, Li W,et al,2024.Study on blasting fragmentation mechanism of burnt rock in open-pit coal mine[J].Scientific Reports,14(1):5034. | |
| Li Jiaqing,2021.Numerical simulation and theoretical analysis of ice blast research[J].Technology Wind,(7):13-14. | |
| Li Q,2021.A blow-up result for a system of coupled viscoelastic equations with arbitrary positive initial energy[J].Boundary Value Problems,2021:DOI:10.1186/s13661-021-01538-1. | |
| Li Tong, Chen Ming, Ye Zhiwei,et al,2022.Model experimental study of explosion pressure propagation in concrete water-bearing crack[J].Rock and Soil Mechanics,43(Supp.2):205-213. | |
| Liang Rui, Cao Xiaorui, Zhou Wenhai,et al,2024.Effect of uncoupled charge coefficients on rock blast damage[J].Gold Science and Technology,32(2):306-317. | |
| Ling Tianlong, Wang Yutao, Liu Dianshu,et al,2018.Modified RHT model for numerical simulation of dynamic response of rock mass under blasting load[J].Journal of China Coal Society,43(Supp.2):434-442. | |
| Liu H Z, Wan D Y, Wang M,et al,2024.Effect of blasting stress wave on dynamic crack propagation[J].Computer Modeling in Engineering and Sciences,138(1):349-368. | |
| Liu J C, Gao W,2020.Vibration signal analysis of water seal blasting based on wavelet threshold denoising and HHT transformation[J].Advances in Civil Engineering,Pt.4:4381480.1-4381480.14. | |
| Liu Jiangchao, Gao Wenxue, Wang Lintai,et al,2020.Numerical analysis on the charge structure optimization under hydraulic blasting and its application[J].Journal of Vibration and Shock,39(9):57-62,96. | |
| Liu Jiangchao, Gao Wenxue, Zhang Shenghui,et al,2021.Distribution law of explosion stress on hole wall of water interval charge[J].Acta Armamentarii,42(12):2646-2654. | |
| Liu Migong, Wang Hao, Lin Daneng,et al,2023.Analysis of water medium decoupling ratio and position effect of axial decoupling charge structure[J].Engineering Blasting,29(1):93-101,129. | |
| Ma Sizhou, Liu Kewei, Yang Jiacai,et al,2024.Size distribution characteristics of blast-induced rock fragmentation under decoupled charge structures[J].Explosion and Shock,44(4):122-140. | |
| Niu Qiang,1990.Rock Blasting Mechanisms[M].Shenyang:Northeast Institute of Technology Press. | |
| Qing L, Li X,2024.Meshless analysis of fractional diffusion-wave equations by generalized finite difference method[J].Applied Mathematics Letters,157:109204. | |
| Shen Y, Lin B Q, Liu T,et al,2024.Research on the influence of parallel joints on the extension length and morphology of blasting cracks[J].Computers and Geotechnics,167:106088. | |
| Vaňková I, Nicholls K W, Corr H F J,2021.The nature of ice intermittently accreted at the base of Ronne Ice Shelf,Antarctica,assessed using phase-sensitive radar[J].Journal of Geophysical Research:Oceans,126(10):e2021JC017290. | |
| Wang Xuguang,2010.Blasting Brochure[M].Beijing:Metallurgical Industry Press. | |
| Xu Guanchao, Meng Zhuolun, Zhao Jiwei,2020.Numerical simulation and experimental study on single point blasting of ice jam of the Yellow River[J].Journal of North China University of Water Resources and Electric Power(Natural Science Edition),41(4):22-26. | |
| Xu Y X, Yang G, Hu D,2024.Comparison of surface tension models for the simulation of two-phase flow in an ISPH-FVM coupling method[J].European Journal of Mechanics-B/Fluids,105:57-96. | |
| Ye Zhiwei, Chen Ming, Li Tong,et al,2021a.A simplified method for calculating peak pressure of borehole wall under water-coupling contour blasting[J].Rock and Soil Mechanics,42(10):2808-2818. | |
| Ye Zhiwei, Chen Ming, Li Tong,et al,2021b.A calculation method of the peak pressure on borehole wall for low decoupling coefficient charge blasting[J].Explosion and Shock Waves,41(6):119-129. | |
| Zong Qi, Xuan Shiqing,1997.Quasi-static pressure of hydro pressure blasting and its destruction judgement[J].West-China Exploration Engineering,(2):41-42. | |
| Zuo J J, Yang R S, Min G,et al,2021.Studies on directional breaking controlled theory of slotted cartridge blasting for rock[J].Arabian Journal of Geosciences,14(18 Pt.2):1928-1. | |
| 费鸿禄,李守巨,何庆志,1992.光面爆破装药不耦合系数的计算[J].爆炸与冲击,(3):270-274. | |
| 费鸿禄,甄帅,李文焱,等,2022.高原多年含水冻岩爆破炮孔温度—水分场耦合分析[J].爆破,39(4):32-43. | |
| 黄瑞彬,2021.露天深孔预裂爆破水耦合影响的数值试验研究[D].成都:西南交通大学. | |
| 李佳庆,2021.冰体爆破的数值模拟与理论分析研究[J].科技风,(7):13-14. | |
| 李桐,陈明,叶志伟,等,2022.混凝土含水裂隙中爆炸压力传播的模型试验研究[J].岩土力学,43(增2):205-213. | |
| 梁瑞,曹晓睿,周文海,等,2024.不耦合装药系数对岩体爆破损伤的影响[J].黄金科学技术,32(2):306-317. | |
| 凌天龙,王宇涛,刘殿书,等,2018.修正RHT模型在岩体爆破响应数值模拟中的应用[J].煤炭学报,43(增2):434-442. | |
| 刘江超,高文学,王林台,等,2020.水封爆破装药结构优化数值分析及其应用[J].振动与冲击,39(9):57-62,96. | |
| 刘江超,高文学,张声辉,等,2021.水间隔装药孔壁爆炸应力分布规律[J].兵工学报,42(12):2646-2654. | |
| 刘敉共,王浩,林大能,等,2023.轴向不耦合装药结构水介质不耦合系数及位置效应分析[J].工程爆破,29(1):93-101,129. | |
| 马泗洲,刘科伟,杨家彩,等,2024.不耦合装药下岩石爆破块体尺寸的分布特征[J].爆炸与冲击,44(4):122-140. | |
| 钮强,1990.岩石爆破机理[M].沈阳:东北工学院出版社. | |
| 汪旭光,2010.爆破手册[M].北京:冶金工业出版社. | |
| 许冠超,孟卓伦,赵继伟,2020.黄河冰凌单点爆破的数值模拟与试验研究[J].华北水利水电大学学报(自然科学版),41(4):22-26. | |
| 叶志伟,陈明,李桐,等,2021a.一种水耦合轮廓爆破孔壁压力峰值的简化计算方法[J].岩土力学,42(10):2808-2818. | |
| 叶志伟,陈明,李桐,等,2021b.小不耦合系数装药爆破孔壁压力峰值计算方法[J].爆炸与冲击,41(6):119-129. | |
| 宗琦,宣始青,1997.水压爆破时的准静压作用及其破坏判据[J].西部探矿工程,(2):41-42. |
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