RU2068014C1 - Procedure for extracting rhenium - Google Patents

Abstract

FIELD: non-ferrous hydrometallurgy. SUBSTANCE: rhenium is extracted from acidic sulfate-chloride and chloride solutions with an extract containing a primary, secondary or tertiary amine with an organic acid added selected from the group: synthetic fatty acids, naphthenic acids, higher isocarboxylic acids, monothionaphthenic acids, and di(2-ethylhexyl)phosphoric acid. EFFECT: proposed procedure which may be used when processing sulfate-chloride solutions from the treatment of the industrial products of the lead-zinc production. 7 tbl

Description

 The invention relates to the field of hydrometallurgy of non-ferrous metals and relates to methods for extracting rhenium from complex solutions, in particular from zinc sulfate-chloride solutions obtained in the processing of industrial products of lead-zinc production, for example, lead dust, sublimates, sludges, etc.

 The need to create the present invention is determined by the complexity of existing technological schemes for the extraction of rhenium from acidic solutions, as well as the high consumption of reagent (acid and alkali) in the process of its extraction.

 Known methods for the extraction of rhenium from solutions by ion exchange and sorption [1] As anion exchangers, various anion exchange resins are used: AM-1, EDE-10P, AB-27 and others, activated carbons as a sorbent. The disadvantages of these methods are the low rate of extraction of rhenium to anion exchange resin or coal, as well as the difficulty of desorption of rhenium from resins or coal (perchloric acid or solutions of rhodanum ammonium in hydrochloric acid are used for desorption).

 According to the method [2], the extraction of rhenium from leach solutions of lead-zinc sublimates is based on its extraction with tributyl phosphate (TBP). The disadvantage of this method is the low degree of extraction of rhenium due to the weak extraction properties of TBP.

(1)
Из (1) видно, что это приводит не только к загрязнению экстрагента, но и к ухудшению экстракции рения. В дальнейшем на стадии реэкстракции растворами аммиака это вызывает образование осадков, т. е. реэкстракция рения осуществляется в твердофазном варианте, при этом совместно с рением реэкстрагируются и переходят в осадок кадмий и цинк. Состав осадка зависит от условий реэкстракции, но кроме перрената аммония он содержит аммиакаты кадмия и цинка, Ме(NH₃)₄(ReO₄)₂, где Ме Сd или Zn. Указанный способ имеет ряд существенных недостатков. В результате реэкстракции раствором аммиака получают осадок перрената аммония с высоким содержанием сопутствующих металлов цинка, кадмия и т.п. Для очистки от примесей с целью получения товарного продукта требуется многостадийная переработка осадка, включающая его растворение и ряд перекристиллизаций. Это приводит к дополнительным оборотам и потерям рения с промпродуктами.The closest to the described method in technical essence and the achieved result is a method of extracting rhenium from solutions of leaching dust agglomeration of lead products using trialkylamine (TAA) in an organic solvent with the addition of alcohols, followed by reextraction with ammonia solutions and regeneration of the extractant with sulfuric acid solutions [3] The presence of chloride ions in sulfate solutions containing impurities of metals, in particular zinc and cadmium, leads to the extraction of these impurities in the extractant in the composition of m tallogalogenidnyh complexes together with rhenium (see. the reaction 1)

(one)
It can be seen from (1) that this leads not only to contamination of the extractant, but also to a deterioration of rhenium extraction. Subsequently, at the stage of reextraction with ammonia solutions, this causes the formation of precipitation, i.e., rhenium is reextracted in the solid-phase form, while cadmium and zinc are reextracted and pass into the precipitate. The composition of the precipitate depends on the conditions of stripping, but in addition to ammonium perrenate, it contains cadmium and zinc ammonia, Me (NH ₃ ) ₄ (ReO ₄ ) ₂ , where Me is Cd or Zn. The specified method has a number of significant disadvantages. As a result of reextraction with an ammonia solution, a precipitate of ammonium perrenate with a high content of accompanying metals of zinc, cadmium, etc. is obtained. For purification from impurities in order to obtain a marketable product, a multi-stage processing of the precipitate is required, including its dissolution and a series of recrystallizations. This leads to additional turnover and loss of rhenium with industrial products.

 In addition, solid-phase rhenium reextraction complicates the technological process and hardware design due to the need to separate the three phases of aqueous, organic and sediment. Precipitation, as a rule, contain a certain amount of extractant, which leads to contamination of the final product and additional losses of extractant.

 The aim of the invention is to simplify the technology for the extraction of rhenium from complex, acidic sulfate-chloride and chloride solutions, including hardware, by carrying out re-extraction of rhenium in the liquid-phase version, as well as obtaining sharp paths with a much lower content of related mat metals (zinc, cadmium) suitable for the production of ammonium perpenate without further purification. At the same time, high rhenium recovery at the extraction stage remains.

This goal is achieved in that, in contrast to the known method of extracting rhenium from acid sulfate-chloride solutions containing metal impurities, extraction with trialkylamine (TAA) with the addition of alcohols, followed by re-extraction with alkaline reagents and regeneration of the organic phase, in the proposed method, the extraction is carried out primary, secondary or tertiary amines with the introduction of non-chelating organic acids into these extractants, in particular synthetic fatty acids (FFA), higher isocarboxylic acids (B IR), di-2-ethylhexylphosphoric acid (D2EGPA), naphthenic acids (NK) or monothionaphthenic acids (MNTE). The interaction of metal cations with anions of a non-chelating organic acid is carried out in the form of normal salt formation, without the formation of chelate compounds in which an anion of an organic acid is attached to a metal cation by two or more atoms [4]
The addition of one of the above organic acids to organic amines while maintaining a high degree of rhenium extraction at the extraction stage makes it possible to re-extract rhenium with alkaline reagents without precipitation. This is due to the fact that in the proposed method, the accompanying metals (zinc, cadmium, etc.) are not re-extracted with rhenium, but remain in the organic phase, forming compounds with organic acids. Rhenium is re-extracted with alkaline reagents selectively, as a result of which an almost complete separation of rhenium and coextracted metals such as zinc, cadmium is achieved, which makes it possible to obtain sufficiently pure rhenium re-extracts. From the obtained reextract, by a single recrystallization, a conditioned product in the form of ammonium perrenate can be obtained. Selective re-extraction of rhenium in the proposed method is carried out in the liquid-phase version, which makes it possible to use simple devices, for example, box-type extractors, in contrast to the prototype, where it is necessary to use special equipment for the separation of aqueous, organic phases and sediment at the stage of re-extraction. Since at the stage of re-extraction in the proposed method there is no precipitation, the loss of extractant with them is reduced.

 To regenerate the extractant, after alkaline re-extraction of rhenium, the organic phase is treated with a solution of sulfuric acid. In this case, the accompanying metals (cadmium, zinc) are transferred to the sulfate solution and sent for further processing, and the organic phase in the sulfate form returns to the cycle.

 The method is illustrated by the following examples.

Example 1. As an anion-exchange extractant, C ₇ -C ₉ fraction trialkylamine (TAA) was used, and the following reagents were used as non-chelating organic acids: neftenic acids (NK), monothionaphthenic acids (MNTK), synthetic C ₇ -C ₉ fatty acids ( FFA), higher isocarboxylic acids of the C ₁₁ -C ₁₉ fraction (VIC), as well as di-2-ethylhexylphosphoric acid (D2EGFK).

From the initial solution of sulfatization of lead dust of the following composition, g / dm ³ : Re 0.1, Cd 30, Zn 50, H ₂ SO ₄ 20, Cl 17, As - 2.5, Fe 2.2, rhenium is extracted with extractants containing 0 , 4 M TAA in kerosene with the addition of 10% 2-ethylhexanol and 1 M non-chelating organic acid. Extraction was carried out at a phase volume ratio of O: B of 1:30 for 3 min. After phase separation, the rhenium content was determined in them. The organic phase (extract) containing rhenium, zinc and cadmium was contacted at 0: B 5: 1 in a solution of sodium hydroxide with a concentration of 3 M for 3 min at room temperature. In the aqueous phase (reextract), after separation of the phases, the content of rhenium, zinc and cadmium was determined.

 The data are given in table. 1.

 As can be seen from this example, conducting the process in the presence of organic non-chelating acids makes it possible to obtain reextracts with a significantly lower content of accompanying metals than in the absence of additives, and to avoid precipitation.

 Example 2. Under the conditions of example 1, an experiment is conducted for 0.4 M solutions of primary amine (aminonitroparaffin ANP-1) and diisododecylamine (DIDA) in kerosene with the addition of 10% 2-ethylhexanol containing 1 M organic acid.

 The results are shown in table. 2.

 This example proves the achievement of a new technical result for mixtures of primary and secondary amines with the above additives.

 To confirm the feasibility of the proposed method and for pure chloride solutions, we give example 3.

Example 3. Rhenium is recovered from a solution containing g / dm ³ : Re 0.1, CdCl ₂ 10, ZnCl ₂ 30, HCl 20 at O: B 1:10 with 0.3 M TAA solutions containing 10% 2-ethylhexanol and 1 M organic acid. The extract is treated with a solution of NaOH (3M) for 3 min at O: B 5: 1.

 The results are shown in table. 3.

 As can be seen from the table, the introduction of organic acids eliminates the formation of precipitation and increases the purity of the reextract.

 Example 4. Under the conditions of example 1, experiments are carried out in which the extractant contains a different amount of anion exchange reagent and an organic acid.

 The results are shown in table. 4.

 The above results indicate that in a wide range of concentrations of amines and organic acids (for example, TAA, VIC, and D2EGFK), precipitation is not observed at the stage of alkaline reextraction, and the cadmium and zinc content in rhenium reextract is much lower than in the absence of additives (see example 1).

 Example 5. An experiment was conducted under the conditions of example 1 for a 0.2 M solution of TAA containing 10% 2-ethylhexanol and 1 M each of VIC and G2EGFK. The extracts were treated with 3 M ammonia solution.

 The results are shown in table. 5.

 The ammonia rhenium extracts obtained in the example are characterized by a low content of impurities, and there are no precipitates.

 Example 6. The organic phase obtained under the conditions of Example 1, after alkaline treatment (stripping), was contacted with a 3 M solution of sulfuric acid at O B 5 1 for 3 minutes. The content of cadmium and zinc in the acid reextract (aqueous phase) and the regenerated extractant was determined. Then, the regenerated extractant was again contacted at 0 B 1 30 with the initial solution for 3 min and the raffinate was analyzed for rhenium content (Table 6).

 This example shows the possibility of reusing extractants without compromising rhenium recovery.

Example 7. In the initial solution of sulfatization of lead dust (composition see example 1), a mother liquor is added after precipitation of ammonium perrenate. The rhenium content in the solution was 0.112 g / dm ³ . From the solution of sulfation of lead dusts, countercurrent extraction of rhenium was carried out at OB 1 30 with a 0.4 M solution of TAA containing 1.0 M VIC and 15% 2-ethylhexanol. For 5 stages of extraction obtained raffinate containing 0.03 g / DM ³ rhenium. The extraction of rhenium at the extraction stage was 97.3%. Rhenium was extracted from the organic phase by a single treatment of the extract with a solution of 2.5 M ammonia at 0 B 5 1. At the same time, a rhenium re-extract containing 16.1 g / dm ^{3 of} rhenium, 0.13 g was obtained. / dm ³ cadmium and 0.05 g / dm ³ zinc. The extraction of rhenium at the stage of re-extraction was 98.6% (in the cyclic extraction-re-extraction process, the degree of re-extraction is close to 100% since the extractant is reverse and un-extracted rhenium returns to the next cycle). Evaporation of rhenium stripping, crystallization and subsequent single recrystallization yielded ammonium perrenate containing 69.3% rhenium. Below is the composition of the sample obtained ammonium perrhenate, as well as the quality requirements for the conditional ammonium perrhenate (AR-0).

 The data are given in table. 7.

 As you can see, the sample meets the necessary requirements, in the conditions of the proposed method received a conditional ammonium perrenate. To obtain a conditional ammonium perrenate prototype requires a significantly larger number of operations.

 Thus, the use of rhenium from acidic sulfate-chloride and chloride solutions of a complex composition of primary, secondary and tertiary amines with the addition of organic acids, such as synthetic fatty acids, naphthenic acids, higher isocarboxylic acids, monothionaphthenic acids or di-2-ethylhexylphosphoric acid , leads to a significant simplification of the process due to the re-extraction of rhenium in the liquid phase version. This allows replacing the periodic re-extraction of rhenium in the solid-phase apparatus with a continuous process in standard extraction apparatus, improving working conditions and reducing the loss of extractant. The resulting rhenium stripping is practically free of impurities accompanying rhenium metals, which simplifies their further processing and reduces the loss of rhenium as a result of a reduction in its turnover with rhenium-containing intermediate products. TTT1 TTT2 TTT3 TTT4

Claims (1)

 A method for extracting rhenium from acidic sulfate-chloride and chloride solutions containing metal impurities, including extraction with an extractant containing a primary, secondary or tertiary amine, alkali solution reextraction and regeneration of the organic phase, characterized in that the extraction is carried out with the introduction of an organic acid of the selected from the series: synthetic fatty acids, naphthenic acids, higher isocarboxylic acids, monothionaphthenic acids or di-2-ethylhexylphosphoric acid.

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