地质不确定条件下采石场长期生产调度优化

IF 1.8 Q3 MINING & MINERAL PROCESSING

Mining Technology-Transactions of the Institutions of Mining and Metallurgy Pub Date : 2021-03-03 DOI:10.1080/25726668.2021.1894398

Trong Vu, T. Bao, C. Drebenstedt, H. Pham, Hoai-Quoc-Trung Nguyen, Duc Nguyen

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引用次数: 2

摘要

水泥生产项目的成功与否取决于原材料的供应。基于资源模型的采石场长期生产调度(LTQPS)是保证水泥厂稳定供应的关键。由于资源模型中勘探数据的稀疏性和未实现生产目标的重大风险因素，地质不确定性是固有的。本研究提出了一个考虑地质不确定性对原材料供应影响的LTQPS随机框架。聚类算法使用多个模拟矿床模型将区块聚集成采矿切口。建立了一种新的随机混合整数规划模型，该模型具有两个目标:使原料混合料的开发成本最小化和不满足生产目标的风险最小化。所提出的框架在越南南部的石灰岩矿床中成功实施，与确定性混合整数规划模型相比，增加了500万吨(Mt)，单位成本降低了30%。

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Optimisation of long-term quarry production scheduling under geological uncertainty to supply raw materials to a cement plant

ABSTRACT The success of a cement production project depends on the supply of raw materials. Long-term quarry production scheduling (LTQPS) based on resource models is essential to maintain a consistent supply to cement plants. Geological uncertainty is inherent due to sparse exploration data in resource models and significant risk factors for not achieving production targets. This research proposes a stochastic framework for LTQPS that considers the impact of geological uncertainty on raw material supply. A clustering algorithm uses multiple simulated deposit models to aggregate blocks into mining cuts. A new stochastic mixed-integer programming model is formulated with two objectives: to minimise the cost for developing the raw mix and the risk of not meeting production targets. The proposed framework is implemented successfully in a limestone deposit in Southern Vietnam, resulting in an increase of 5 million tons (Mt) and a 30% reduction in unit cost over the deterministic mixed-integer programming model.

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来源期刊

Mining Technology-Transactions of the Institutions of Mining and Metallurgy MINING & MINERAL PROCESSING-

CiteScore

2.20

自引率

9.10%

发文量