房柱法采场矿柱数的数值模拟优化

现代矿业 ›› 2013, Vol. 29 ›› Issue (10): 5-9.

房柱法采场矿柱数的数值模拟优化

郝世波

长春黄金设计院

出版日期:2013-10-16 发布日期:2013-11-28

The Numerical Simulation Optimization Research on the Number of Rome and Pillar Method of the Stope Pillar

Hao Shibo

Changchun Gold Design Institute

Online:2013-10-16 Published:2013-11-28

摘要/Abstract

摘要： 山东烟台鑫泰黄金矿业有限责任公司东刘家矿区矿体倾角0°～22°，平均厚度4.17 m，属于二长花岗岩型矿床，采用铲运机出矿的房柱空场嗣后充填法开采。设计采场面积2 400 m2，内有3 m×3 m矿柱14个,采场内矿柱太多给生产造成困难。经优化后，矿柱降至4个，直径增大至5 m。结果表明：矿柱的减少增大了采场作业面积，有利于采场内矿石运输，且圆形支柱比方形更优，给以后采场顶板形成拱形提供便利条件。

关键词: 房柱采场, 矿柱个数, 数值模拟, 优化研究

Abstract: The dip angle of Liujia mining orebody of Shangdong province Xintal gold mining is 0°～22° and the average thickness is 4.17 meters.The liujia mining orebody is belongs to the Monzonitic granite type deposits, so, the room and pillar open stope filling later method is adopted by using the scraper. The stope area is 400 square meters an has 14 pillars. Due to number of the pillar is too much, so it makes the mine production more difficult. Through numerical simulation optimization, the number of pillar reduce to 4, the diameter of pillar increased to 5 meters. The research results indicated that, reducing the number of pillar is good for increasing the stope operation area,and good to the ore transportation in the stope.In addition, according to the experimental results, the round supporting mechanics is better than the square one, witch provide convenient conditions for forming the arch stope roof.

Key words: Room and pillar mining, Number of pillars, Numerical simulation, Optimization research

郝世波. 房柱法采场矿柱数的数值模拟优化[J]. 现代矿业, 2013, 29(10): 5-9.

HAO Shi-Bo. The Numerical Simulation Optimization Research on the Number of Rome and Pillar Method of the Stope Pillar[J]. Modern Mining, 2013, 29(10): 5-9.

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