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Gold Science and Technology ›› 2016, Vol. 24 ›› Issue (6): 112-116.doi: 10.11872/j.issn.1005-2518.2016.06.112

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Transformation Research on the Grading Equipment of Semi-autogenous Mill in a Gold Mine,Qinghai Province

MA Zhongshan1,2,ZHOU Xueqi1   

  1. 1.6th Institute Qinghai  of  Qinghai  Geology and Mineral Exploration,Golmud    816000,Qinghai,China;
    2.Qinghai Engineering Research Center for Gold Mineral Resource Development,Dulan    816100,Qinghai,China
  • Received:2016-06-29 Revised:2016-08-15 Online:2016-12-28 Published:2017-01-22

Abstract:

The SAG(semi-autogenous) mill discharge grading is an important link in improving grinding efficiency of concentrator.The Straight-line vibrating screen classification was used in the SAG mill discharge grading of  a gold mine in Qinghai Province,this serious influenced the stability of the production run,due to the high failure rate of linear vibrating screen,low mill plant operation rate.By changing the linear vibrating screen to cylinder sieve classification,equipment operation rate increased by 1%,beneficiation cost savings of nearly 100 000 yuan.The results show that the trommel screen can achieve the same effect as the linear vibrating screen in the grading equipment of the semi-autogenous mill.Compared with the linear vibrating screen,the trommel screen has the advantages of low energy consumption,low cost,simple structure and convenient maintenance.Thus greatly reducing the labor intensity and equipment maintenance time,improve the dressing plant equipment operation rate.The transformation of the beneficiation plant to enhance the process indicators has the vital significance.

Key words: semi-autogenous mill, linear vibrating screen, trommel screen, hierarchical nesting

CLC Number: 

  • TD953

[1]吴彩斌,杨昊,周意超,等.青海某贫硫金矿石选厂磨矿分级系统优化试验研究[J].黄金科学技术,2015,23(4):30-34.
[2]谭尾琴.选矿厂磨矿分级监控系统设计[D].赣州:江西理工大学,2012.
[3]明平田,吴国民,李飞,等.磨矿分级工艺考察及分析研究[J].有色金属(选矿部分),2012(6):45-48.
[4]王耀,崔振立.一段磨矿分级使用直线振动筛的实践[J].金属矿山,2011(6):308-310.
[5]石立,张国旺,肖骁.金属矿山选矿厂磨矿分级自动控制研究现状[J].有色金属(选矿部分),2013(增):44-49.
[6]郭灵敏,刘俊,麦笑宇.李楼镜铁矿系统磨矿分级优化试验及其考查分析[J].矿冶工程,2014(6):22-25.
[7]左晓辉.某选厂磨矿分级工艺改造与自动化控制系统研究[J].现代矿业,2015(12):71-73,76.
[8]张立申,王卫东.圆筒筛在一次磨矿分级中的应用[J].河北冶金,2000(4):34-36.
[9]董节功,姬建钢,祖大磊,等.刚果(布)某多金属矿单段半自磨流程磨矿设备选型分析[J].矿山机械,2015,43(10):68-73.
[10]唐守营,何智文.湿式半自磨流程在归来庄金矿的应用[J].矿山机械,2012,40(7):139-140.
[11]杜明.最新矿山选矿手册[M].北京:冶金工业出版社,2007:226.
[12]孙时元.最新中国选矿设备手册[M].北京:机械工业出版社,2006:318-328.

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