An improved pillar design methodology

IF 0.9 4区材料科学 Q3 Materials Science

Journal of The South African Institute of Mining and Metallurgy Pub Date : 2022-11-04 DOI:10.17159/2411-9717/1983/2022

K. Jessu, A. Spearing, M. Sharifzadeh

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引用次数: 0

Abstract

Empirical pillar design methods are commonly used in the mining industry. The parameters within which these methods are valid are frequently unknown to the user or ignored. In addition, empirical design may not consider essential parameters such as blasting effects, orebody dip and the presence of geological structures, which all adversely affect the stability of the pillars. This can result in potentially serious pillar design strength over-estimates. Although the commonly based tributary area method is generally conservative, as the spans are seldom that large relative to the depth, failing to consider other relevant parameters can result in errors. Problems associated with an under-designed pillar can range from a local pillar collapse to a catastrophic chain reaction collapse (or run). Over-designed pillars are generally safe but reduce the extraction of the orebody, thus adversely affecting the profitability of the mining operation. We used laboratory tests and numerical modelling to understand the effects of pillar orientation, blasting and the presence of discontinuities on pillar strength. Reduction factors were developed with these models to be implemented in conjunction with the existing empirical pillar design methods. For any pillar or mine design, once it is implemented, the actual performance of the system must be checked regularly by observation and monitoring and adjusted if needed. The pillar design approach outlined in this paper can better optimize the pillar mining method by considering other generally ignored but important parameters, thus improving safety, productivity, and economic aspects.

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一种改进的支柱设计方法

经验矿柱设计方法在采矿业中常用。用户经常不知道或忽略这些方法有效的参数。此外，经验设计可能没有考虑爆破效果、矿体倾角和地质结构的存在等基本参数，这些参数都会对矿柱的稳定性产生不利影响。这可能导致潜在的严重支柱设计强度超出估计值。尽管常用的支流面积法通常是保守的，因为跨度相对于深度很少那么大，但如果不考虑其他相关参数，可能会导致误差。与设计不足的支柱相关的问题可能从局部支柱坍塌到灾难性连锁反应坍塌（或运行）。过度设计的矿柱通常是安全的，但会减少矿体的开采，从而对采矿作业的盈利能力产生不利影响。我们使用实验室测试和数值模拟来了解矿柱方向、爆破和不连续性对矿柱强度的影响。折减系数是用这些模型制定的，将与现有的经验支柱设计方法结合使用。对于任何矿柱或矿山设计，一旦实施，必须通过观察和监测定期检查系统的实际性能，并在需要时进行调整。本文概述的矿柱设计方法可以通过考虑其他通常被忽视但重要的参数来更好地优化矿柱开采方法，从而提高安全性、生产力和经济性。

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

Journal of The South African Institute of Mining and Metallurgy 工程技术-矿业与矿物加工

CiteScore

1.50

自引率

11.10%

发文量

审稿时长

4-8 weeks

期刊介绍： The Journal serves as a medium for the publication of high quality scientific papers. This requires that the papers that are submitted for publication are properly and fairly refereed and edited. This process will maintain the high quality of the presentation of the paper and ensure that the technical content is in line with the accepted norms of scientific integrity.