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现代矿业 ›› 2026, Vol. 42 ›› Issue (05): 38-44,52.

• 采矿工程 • 上一篇    下一篇

基于尖点突变理论的深部铁矿采场跨度优化

张国权1 游子龙2 张增贵1 丰 庆1 张 勇1 王 平2   

  1. 1. 武钢资源集团大冶铁矿有限公司;2. 武汉科技大学资源与环境工程学院
  • 出版日期:2026-05-25 发布日期:2026-06-10

Optimization of Stope Span in Deep Iron Mine Based on Cusp Catastrophe Theory

  1. 1. Daye Iron Mine Co.,Ltd.,WISCO Resources Group; 2. College of Resource and Environmental Engineering,Wuhan University of Science and Technology
  • Online:2026-05-25 Published:2026-06-10

摘要: 为解决深部金属矿山高地应力引发的围岩失稳问题,以某矽卡岩型铁矿-450~-540 m 中段为工程背景,针对分段空场嗣后充填法存在的采场参数不合理、开采稳定性差等问题,开展矿 房跨度优化研究。采用尖点突变理论构建顶板固支梁力学模型,计算得出顶板理论极限跨度为 17.24 m,据此初选 12,15,18 m 共 3 组跨度方案;依托 FLAC3D开展数值模拟,基于 Hoek-Brown 方程 折算岩体参数,采用摩尔-库仑准则对比分析围岩稳定性。结果表明:矿房跨度与顶板沉降、拉应 力呈非线性正相关;12,15 m 跨度顶板沉降量分别为 29.00,36.68 mm,稳定性良好;18 m 跨度沉降 达 52.30 mm,塑性区面积较 12 m 跨度扩大 115%,围岩呈渐进式破坏。综合安全与生产效率,确定 最优矿房跨度为 15 m。该研究形成的理论结合数值模拟优化方法,可为同类深部矿山采场结构设 计及围岩管控提供参考。

关键词: 尖点突变理论, 分段空场嗣后充填法, 采场结构参数, 数值模拟, 深部开采, 围岩稳定性

Abstract: To solve the surrounding rock instability induced by high in-situ stress in deep metal mines,taking the -450~-540 m sublevel of a skarn-type iron mine as the engineering background,an op⁃ timization study on ore chamber span is conducted targeting the problems of unreasonable stope parameters and poor mining stability existing in the sublevel open stoping with backfilling method. A fixed-beam me⁃ chanical model of the roof is established by the cusp catastrophe theory,and the theoretical ultimate span of the roof is calculated to be 17.24 m,based on which three preliminary span schemes of 12 m,15 m and 18 m are selected. Numerical simulation is carried out with FLAC3D ,rock mass parameters are converted based on the Hoek-Brown criterion,and the Mohr-Coulomb criterion is adopted to compare and analyze the surrounding rock stability. The results show that the ore chamber span presents a non-linear positive cor⁃ relation with roof subsidence and tensile stress. The roof subsidence of 12 m and 15 m spans is 29.00 mm and 36.68 mm respectively,with good stability. The subsidence of 18 m span reaches 52.30 mm,and the plastic zone area is 115% larger than that of 12 m span,indicating progressive failure of surrounding rock. Considering both safety and production efficiency,the optimal ore chamber span is determined as 15 m. The research method integrating theoretical analysis with numerical simulation can provide reference for stope structure design and surrounding rock control in similar deep mines.

Key words: cusp catastrophe theory, sublevel open stoping with backfilling method, stope structural parameters, numerical simulation, deep mining, surrounding rock stability