[an error occurred while processing this directive] [an error occurred while processing this directive] [an error occurred while processing this directive]
[an error occurred while processing this directive]

Gold Science and Technology >

2024 , Vol. 32 >Issue 3: 511 - 522

DOI: https://doi.org/10.11872/j.issn.1005-2518.2024.03.001

Mining Technology and Mine Management

Optimization of Stope Sidewall Controlled Blasting Parameters for High-Stress Fan-Shaped Medium-Depth Hole

  • Bo LI , 1 ,
  • Chen WEN 2 ,
  • Xiuzhi SHI , 1
Expand
  • 1. School of Resources and Safety Engineering, Central South University, Changsha 410083, Hunan, China
  • 2. Zijin(Changsha) Engineering Technology Co. , Ltd. , Changsha 410017, Hunan, China

Received date: 2023-12-14

  Revised date: 2024-01-14

  Online published: 2024-07-05

Fold

Abstract

At present,most of the fan-shaped hole stope blasting is difficult to achieve direct control of the sidewalls,and fan-shaped holes due to the special characteristics of its own structure can not be avoided to cause a certain amount of over-excavation or under-excavation.Aiming at the problem of controlling the sidewalls of the blasting of fan-shaped holes in the stope,a concept of constructing the fan-shaped holes close to the sidewalls into vertical parallel holes for controlling the sidewalls was proposed.Sidewall controlled blasting technology generally utilizes air-uncoupled charge structures to achieve.The model parameters of four groups of parallel boreholes under the uncoupling coefficient and spacing matching were obtained by theoretical calculation.The numerical simulation was carried out by LS-DYNA,and the blasting crack propagation of the four groups of models without in-situ stress and in different directions of in-situ stress was compared.The stress conditions of the three schemes are different.In scheme 1,four models are numerically simulated under the condition of no ground stress.In scheme 2,when the direction of the maximum horizontal stress is the same as that of the stope layout,30 MPa is loaded in the X direction and 60 MPa in the Y direction.In scheme 3,when the direction of maximum horizontal stress is perpendicular to the direction of stope layout,60 MPa is loaded in X direction and 30 MPa is loaded in Y direction.After analyzing the blasting crack propagation and blasting effect,it is found that high geostress promotes the propagation of blasting cracks in the direction of the maximum stress.When the stope is arranged parallel to the direction of maximum horizontal stress,the propagation of blasting cracks in the rock between the lines of the blast holes is promoted,which is beneficial to the breaking of rock.The propagation of blasting cracks in the rock between the blast hole and the surrounding rock will be restricted,which is beneficial to the protection of the sidewalls.When the stope is arranged vertically along the direction of the maximum horizontal stress,the propagation of blasting cracks in the rock is promoted,which is not beneficial to the protection of the sidewalls.Therefore,the direction of the stope layout should be the same as the direction of the maximum horizontal principal stresses.Statistics on the four models of excavation area damage rock,the uncoupling coefficient of 1.65,neighboring parallel hole spacing of 1.1 m is the most reasonable.Industrial experiments were carried out in the test stope,using the optimized blasting parameters for blasting,and the sidewalls were smooth and stable after the stope was mined,which verified the reasonableness of the blasting scheme.

Key words: sidewall controlled blasting; high geo-stress; theoretical calculations; numerical simulation; fan-shaped hole; blasting crack propagation

Cite this article

Bo LI , Chen WEN , Xiuzhi SHI . Optimization of Stope Sidewall Controlled Blasting Parameters for High-Stress Fan-Shaped Medium-Depth Hole[J]. Gold Science and Technology, 2024 , 32(3) : 511 -522 . DOI: 10.11872/j.issn.1005-2518.2024.03.001

[an error occurred while processing this directive]

http://www.goldsci.ac.cn/article/2024/1005-2518/1005-2518-2024-32-3-511.shtml

References

Publishing order | Descend order by publishing year | Descend order by cited within
Dai Jun2001.Calculation of radii of the broken and cracked areas in rock by a long charge explosionc[J].Journal of Liaoning Technical University(Natural Science)20(2):144-147.

Dai Jun2013.Dynamic Behaviors and Blasting Theory of Rock[M].Beijing:Metallurgical Industry Press.

Fan D Y Liu X S Tan Y L,et al,2020.Numerical simulation research on response characteristics of surrounding rock for deep super-large section chamber under dynamic and static combined loading condition[J].Journal of Central South University27(12):3544-3566.

Huo Xiaofeng Shi Xiuzhi Gou Yonggang2019.Simulation of crack growth in sidewall controlled blasting and parameter optimization[J].Blasting36(1):21-28.

Li Hongchao2016.The Study of the Rock RHT Model and to Determine the Values of Main Parameters[D].Beijing:China University of Mining and Technology (Beijing).

Liang Dongbiao2019.Study on the Influence of Periphery Hole Blasting Parameters on Surrounding Rock Damage and Overbreak and Underbreak of Tunnel[D].Chengdu:South-west Jiaotong University.

Luo S Yan P Lu W B,et al,2021.Effects of in-situ stress on blasting damage during deep tunnel excavation[J].Arabian Journal for Science and Engineering46(11):11447-11458.

Meng N K Bai J B Chen Y,et al,2021.Stability analysis of roadside backfill body at gob-side entry retaining under combined static and dynamic loading[J].Engineering Failure Analysis,127:105531.

Peng J Y Zhang F P Du C,et al,2020.Effects of confining pressure on crater blasting in rock-like materials under electric explosion load[J].International Journal of Impact Engineering,139:103534.

Song Junsheng Wang Yanbing Gao Xiangtao,et al,2016.The mechanism of directional fracture controlled blasting and its application[J].Journal of Mining Science and Technology1(1):16-28.

Tong Xiaodong2020.Study on Optimization of Smooth Blasting Parameters and Over-Under Excavation in Karst Tunnel[D].Chongqing:Chongqing Jiaotong University.

Wen Chen Qiao Qiuqiu Qiu Xianyang,et al,2023.Simulation of crack propagation induced by short delay blasting with blastholes in a combined fan pattern for deep well[J].Mining and Metallurgical Engineering43(1):26-31.

Xie L X Lu W B Zhang Q B,et al,2017.Analysis of damage mechanisms and optimization of cut blasting design under high in-situ stresses[J].Tunnelling and Underground Space Technology,66:19-33.

Xu Ying Gu Keke Ge Jinjin,et al,2022.Experimental study on effect of charge uncoupling coefficient on crack propagation in rock by blasting under initial in-situ stresses[J].Blasting39(4):1-9.

Xu Ying Zong Qi2000.Theoretical analysis on the parameters of smooth blasting soft mat layer charging construction[J].Journal of China Coal Society25(6):610-613.

Yan Shilong Xu Ying2005.Numerical simulation of water-coupled charge rock blasting mechanism [J].Chinese Journal of Underground Space and Engineering1(6):921-924,943.

Yang Yuezong2018.Research into the Parameter Optimization of Smooth Blasting and Application in Xinlin Tunnel[D].Xi’an:Xi’an University of Architecture and Technology.

Yi C P Sjöberg J Johansson D,et al,2017.A numerical study of the impact of short delays on rock fragmentation[J].International Journal of Rock Mechanics and Mining Sciences,100:250-254.

Yin Shunlang2016.Study on Blasting Damage Scale by Uncoupling Charge in Typical Strata in Chongqing[D].Chongqing:Chongqing Jiaotong University.

Zhang F P Peng J Y Qiu Z G,et al,2017.Enhancement of low-contrast thermograms for detecting the stressed tunnel in horizontally stratified rocks[J].Engineering Geology,220:266-273.

Zong Qi Lu Pengju Luo Qiang2005.Theoretical study on axial decoupling coefficients of smooth blasting with air cushion charging construction[J].Chinese Journal of Rock Mechanics and Engineering24(6):1047-1051.

戴俊,2001.柱状装药爆破的岩石压碎圈与裂隙圈计算[J].辽宁工程技术大学学报(自然科学版)20(2):144-147.

戴俊,2013.岩石动力学特性与爆破理论[M].北京:冶金工业出版社.

霍晓锋,史秀志,苟永刚,2019.边帮控制爆破裂纹扩展模拟及参数优化[J].爆破36(1):21-28.

李洪超,2016.岩石RHT模型理论及主要参数确定方法研究[D].北京:中国矿业大学(北京).

梁东彪,2019.周边孔爆破参数对隧道围岩损伤及超欠挖的影响研究[D].成都:西南交通大学.

宋俊生,王雁冰,高祥涛,等,2016.定向断裂控制爆破机理及应用[J].矿业科学学报1(1):16-28.

童小东,2020.岩溶隧道光面爆破参数优化与超欠挖控制研究[D].重庆:重庆交通大学.

温晨,乔秋秋,邱贤阳,等,2023.深井扇形组合孔短延时爆破裂纹扩展模拟研究[J].矿冶工程43(1):26-31.

徐颖,顾柯柯,葛进进,等,2022.装药不耦合系数对初始地应力下岩石爆破裂纹扩展影响的试验研究[J].爆破39(4):1-9.

徐颖,宗琦,2000.光面爆破软垫层装药结构参数理论分析[J].煤炭学报25(6):610-613.

颜事龙,徐颖,2005.水耦合装药爆破破岩机理的数值模拟研究 [J].地下空间与工程学报1(6):921-924,943.

杨跃宗,2018.新林隧道光面爆破参数优化研究及工程应用[D].西安:西安建筑科技大学.

殷顺浪,2016.重庆典型地层不耦合装药岩石爆破损伤范围研究[D].重庆:重庆交通大学.

宗琦,陆鹏举,罗强,2005.光面爆破空气垫层装药轴向不耦合系数理论研究[J].岩石力学与工程学报24(6):1047-1051.

Options
Outlines

/

[an error occurred while processing this directive]