采用中心组合设计控制磨矿工艺参数,降低磷矿选矿中泥质含量

IF 1.2 Q3 GEOSCIENCES, MULTIDISCIPLINARY Rudarsko-Geolosko-Naftni Zbornik Pub Date : 2022-01-01 DOI:10.17794/rgn.2022.3.11
G. S. Abdelhaffez, M. S. Abd-Elwahed, M. Hefni
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引用次数: 3

摘要

磷矿磨矿过程中产生的超细颗粒会造成空气污染问题,特别是对选矿厂,浮选池和过滤装置造成污染。小于38 μm的颗粒是磷矿选矿阶段的不良后果之一,其中细粉或超细粉占磷酸盐量的10 - 30%,被视为损失。此外,通过减少这些颗粒来保持额外的磷酸盐量将带来若干好处,包括尽量减少处置矿泥对环境的影响,并加强磷矿选矿过程的经济影响。本文旨在最大限度地利用有用的磷酸盐颗粒,减少泥,而不是用传统的技术做更多的工作。这一目标可以通过在研磨过程中通过确定最佳操作条件来增加所需尺寸的磷酸盐(目标)颗粒的百分比来实现,这将减少泥的数量。中心复合设计(CCD)用于确定需要评估的实验数量,并创建一个预测模型,用于确定最佳操作参数。优化结果表明,在t (5.1 min)、v(42.6%)、s(81.2%)和c(50.7%)的磨削条件下,得到的最大目标为87.6%。式中t、v、s、c分别为研磨时间、球体占用体积、转速相对临界转速的百分比(%)和固相体积浓度(%)。
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CONTROLLING GRINDING PROCESS PARAMETERS USING CENTRAL COMPOSITE DESIGN TO REDUCE SLIMES IN PHOSPHATE ORE BENEFICIATION
Ultrafine particles resulting from the grinding operations of phosphate ore cause problems of air pollution, and of the beneficiation plants particularly, flotation cells and filtration units. Particles of less than 38 μm are one of the undesirable consequences of the phosphate ore beneficiation stage, where fine or ultrafine powder accounts for 10–30 percent of phosphate quantities and is regarded as a loss. Furthermore, maintaining additional amounts of phosphate by reducing these particles will provide several benefits, including minimizing the environmental implications of slime disposal and enhancing the economic impact of the phosphate ore beneficiation process. This paper aims to maximize the useful phosphate particles and reduce the slime instead of doing even more work with traditional techniques. This goal might be attained by increasing the percent of particles of the desired size of the phosphate (Target) during the grinding process by determining the optimal operational conditions, that will reduce the amount of slime. The central composite design (CCD) is used to identify the number of experiments to be evaluated and to create a predictive model to be used for determining the optimal operation parameters. As a result of the optimization process, a maximum Target of 87.6% was obtained at grinding conditions t (5.1 min), v (42.6%), s (81.2%), and c (50.7%). Where t, v, s, and c stand for grinding time, occupied volume of ball, rotational speed percent from critical speed (%) and solid concentration by volume (%) respectively.
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来源期刊
CiteScore
2.50
自引率
15.40%
发文量
50
审稿时长
12 weeks
期刊最新文献
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