Rational technology for separation of yttrium-group rare-earth elements

IF 0.6 4区 材料科学 Q4 METALLURGY & METALLURGICAL ENGINEERING Russian Journal of Non-Ferrous Metals Pub Date : 2022-06-15 DOI:10.17073/0021-3438-2022-3-21-29
A. Valkov, V. Petrov
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Abstract

   The paper studies the features of the extraction technology used to separate yttrium-group rare-earth elements taking into account sharply reducing prices for individual oxides. The latter, along with the low prices for lanthanum and cerium oxides, is associated with a predominant increase in the consumption of praseodymium and neodymium and a slow increase in the consumption of other rare-earth elements (REE), except for terbium and dysprosium. Since all REE are extracted from rare-earth concentrates, less marketable ones are stored or sold at extremely low prices. Elements such as samarium, europium, gadolinium, dysprosium are used in high-tech instruments and devices. At the same time, some low-profit production is possible, but process solutions must certainly be developed providing for minimum costs and be the most cost-effective. The authors propose a technology for separating yttrium-group elements including yttrium isolation stages in a single-stage mode by extraction with a mixture of three extractants (25 vol.% trialkylmethylammonium nitrate – 20 vol. % tributyl phosphate – 20 vol.% higher isomeric carboxylic acid) followed by separation of the triad of elements (samarium-europium-gadolinium) by extraction with organophosphoric acids: 30 vol.% solution of di-2-ethylhexylphosphoric acid or 30 vol.% solution of bis(2,4,4-trimethylpentyl)-phosphinic acid. At the last operation, yttrium-group REE concentrates are isolated simultaneously. The process is conducted in the conditions of complete internal irrigation with the 30 vol.% solution of bis(2,4,4-trimethylpentyl)-phosphinic acid used as an extractant. Initially, all the extraction cascade cells are filled with the initial solution. Separation zones are formed in the extraction cascade with the accumulation of terbium-dysprosium, holmium-erbium and thulium-ytterbium-lutetium concentrates in some cells. Once the products are accumulated, the concentrate solution is drained from cells, and the process starts again. If there is a need in some yttrium-group element, the corresponding binary or ternary concentrate is separated with the isolation of the element required.
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钇族稀土元素的合理分离技术
考虑到个别氧化物价格的急剧下降,本文研究了分离钇族稀土元素的萃取技术的特点。后者,加上镧和铈氧化物价格低廉,与镨和钕的消费显著增加以及除铽和镝以外的其他稀土元素(REE)的消费缓慢增加有关。由于所有的稀土元素都是从稀土精矿中提取出来的,所以不太畅销的稀土被储存起来,或者以极低的价格出售。钐、铕、钆、镝等元素被用于高科技仪器和设备。与此同时,一些低利润的生产是可能的,但是必须开发出最低成本和最具成本效益的工艺解决方案。作者提出了一种分离钇族元素的技术,包括用三种萃取剂(25体积%硝酸三烷基甲基铵- 20体积%磷酸三丁酯- 20体积%高异构体羧酸)混合萃取,在单级模式下分离钇族元素,然后用有机磷酸萃取分离三价元素(钐-铕-钆)。30体积%的二-2-乙基己基磷酸溶液或30体积%的二(2,4,4-三甲基戊基)膦酸溶液。最后一道工序同时分离钇族稀土精矿。该工艺是在完全内灌的条件下进行的,用30%的(2,4,4-三甲基戊基)膦酸溶液作为萃取剂。最初,所有的萃取级联槽都充满初始溶液。在萃取级联中,随着铽-镝、钬-铒和铥-镱-镥精矿在某些细胞中的积累,形成分离带。一旦产品积累起来,浓缩溶液就从细胞中排出,然后重新开始这个过程。如果需要某些钇族元素,则分离出相应的二元或三元精矿,并分离出所需的元素。
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来源期刊
Russian Journal of Non-Ferrous Metals
Russian Journal of Non-Ferrous Metals METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
1.90
自引率
12.50%
发文量
59
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.
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