Using reagents in the form of inverse microemulsion for lead and zinc sulfide flotation

IF 0.6 4区材料科学 Q4 METALLURGY & METALLURGICAL ENGINEERING

Russian Journal of Non-Ferrous Metals Pub Date : 2022-08-17 DOI:10.17073/0021-3438-2022-4-15-24

V. I. Bragin, N. F. Usmanova, E. Burdakova, A. A. Kondratieva

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Abstract

The paper presents the results of studies on the use of collecting agents in the form of an inverse microemulsion (IМE) of the «water in oil» type (i.e. suspended water droplets are in the oil phase) for the flotation extraction of lead and zinc minerals. Lead and zinc concentrates, lead-zinc ore were used as initial samples for flotation. The content of galena in the lead concentrate was 74.7 %, and the content of sphalerite in zinc was 78.7 %. Basic collecting agents in the IМE composition were potassium butyl xanthate (PBX) and kerosene. A nonionic surfactant (NSA) was used for IМE stabilization. Casein was used as additives to main reagents to remove the negative effect of osmotic pressure during the IМE preparation. Casein was transformed into the active soluble form using sodium sulfide. The particle size in the inverse microemulsion was 12.38 nm. In flotation tests, the following options for feeding reagents to the flotation pulp were studied: IМE, IМE + frother, potassium butyl xanthate + frother. The T-92 reagent was used as a frother. PBX consumption as part of IME and in the traditional feeding was 26 g/ton. The results of laboratory tests showed that the method of feeding flotation reagents in the form of IМE leads to both an increase in the flotation rate of lead and zinc sulfides and an increase in their recovery into a foam product. In addition to the increased flotation speed, tests with the use of IМE in the bulk lead-zinc ore flotation cycle showed an increase in extraction into the ultimate concentrate by 10.8 % for lead, by 38.5 % for zinc, in comparison with the traditional feeding of reagents (collector + frother). An increased selectivity of the IМE effect in relation to zinc sulfides, in comparison with lead sulfides, was noted. The flotation rate coefficient of sphalerite is 7.8 times greater than that of galena. An increase in extraction into the ultimate zinc concentrate is also higher and amounted to 16.78 %, while for the lead concentrate it is 1.9 % under the same conditions.

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以反相微乳液形式浮选硫化铅锌

本文介绍了“油中水”型(即悬浮的水滴在油相中)反相微乳液(IМE)形式的捕收剂在铅锌矿物浮选萃取中的应用研究结果。以铅锌精矿、铅锌矿石为初始浮选样品。铅精矿中方铅矿含量为74.7%，锌精矿中闪锌矿含量为78.7%。IМE组成中的碱性捕集剂为丁基黄药钾(PBX)和煤油。非离子表面活性剂(NSA)用于IМE稳定化。在IМE制备过程中，以酪蛋白作为主要试剂的添加剂，消除渗透压的负面影响。用硫化钠将酪蛋白转化为活性可溶性形式。反相微乳液粒径为12.38 nm。在浮选试验中，研究了浮选矿浆的投料方式:IМE、IМE +起泡剂、丁基黄药钾+起泡剂。T-92试剂被用作起泡剂。作为IME和传统饲养的一部分，PBX的消耗量为26克/吨。实验室试验结果表明，以IМE形式投喂浮选药剂的方法，既提高了硫化铅和锌的浮选率，又提高了硫化铅和锌的泡沫回收率。除了提高浮选速度外，在铅锌矿浮选循环中使用IМE的试验表明，与传统的试剂(捕收剂+起泡剂)相比，铅的最终精矿提取率提高了10.8%，锌的最终精矿提取率提高了38.5%。注意到，与硫化铅相比，IМE效应对硫化锌的选择性增加。闪锌矿的浮选速率系数是方铅矿的7.8倍。最终锌精矿的提取率提高了16.78%，铅精矿在相同条件下的提取率提高了1.9%。

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来源期刊

Russian Journal of Non-Ferrous Metals METALLURGY & METALLURGICAL ENGINEERING-

CiteScore

1.90

自引率

12.50%

发文量

审稿时长

3 months

期刊介绍： Russian Journal of Non-Ferrous Metals is a journal the main goal of which is to achieve new knowledge in the following topics: extraction metallurgy, hydro- and pirometallurgy, casting, plastic deformation, metallography and heat treatment, powder metallurgy and composites, self-propagating high-temperature synthesis, surface engineering and advanced protected coatings, environments, and energy capacity in non-ferrous metallurgy.