RU2584626C1 - Method for extraction of holmium (iii) from salt solutions - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to production of rare-earth metals or their oxides from lean or industrial raw material using floatation extraction. Method to extract holmium (III) from water phases involves floatation extraction using organic phase and collector. At that, organic phase used is isooctyl alcohol, and collector is anionic surfactant, sodium dodecyl sulfate in concentration corresponding to stoichiometry: Ho⁺³+3NaDS=Ho(DS)₃+3Na⁺, where Ho⁺³ is holmium (III) cation, NaDS is sodium dodecyl sulfate. Floatation extraction is carried out at pH from 5.3 to 9.5 and ratio of organic and aqueous phases from 1/20 to 1/40.

EFFECT: method enables to achieve high degree of extraction of holmium (III) from solution of its salts.

1 cl, 1 dwg, 1 ex

Description

The invention relates to enrichment, in particular to methods for producing rare earth metals (REM) or their oxides from poor or man-made materials using the method of flotation extraction.

A known method of extraction extraction and separation of solid polymer electrolytes (TPE) and rare earth elements (REE) from nitric acid solutions (RF patent No. 2106030, published 02.27.1998). The extraction and separation of TPE and REE from nitric acid liquid waste is carried out by extraction with a solution of zirconium salt of organophosphorus acid, mainly dibutylphosphoric acid (DBPK) in a neutral organophosphorus reagent. As an organic reagent, tributyl phosphate of a concentration of 5-45 vol.% Is mainly used. % in an inert diluent. During the extraction process, the molar ratio Zr / DBPC = 1 / 50-1 / 4. The extractant is compatible with the Purex Process extraction technology. TPE and REE are separated by washing the extractant with a solution of nitric acid at a concentration of 3-12 mol / L, after which REE is reextracted. The reverse extractant is regenerated by removal of the zirconium salt of the organophosphorus acid by carbonate-alkaline washing.

The disadvantage is the poor selectivity of the method and the impossibility of further separation of individual REEs exclusively in acidic media.

A known method of extracting rare earth elements from technological and productive solutions and pulps (RF patent No. 2484162, published on 06/10/2013). A method for extracting rare earth elements from solutions containing iron (III) and aluminum includes sorption of rare earth elements on a sorbent. Ampholyte with iminodiacetate functional groups is used as a sorbent. Sorption is carried out after preliminary neutralization or acidification of the solution to pH = 4-5 with any alkaline or acidic agent, followed by the introduction of ampholyte into the resulting pulp without separation of the solid part. Sorption is carried out with an ampholyte: pulp ratio of 1: 50-1: 150, a contact time of phases of 3-6 hours, and in the presence of a reducing agent.

The disadvantage of this method is the long contact time of the phases.

There is a universal method for the selective extraction of salts of transition, rare earth and actinide elements from multicomponent solutions using nanoporous materials (RF patent No. 2472863, published January 20, 2013), includes selective extraction of salts in the volumes of nanopores of electrically conductive materials due to the effect of the electrostatic interaction of the solvated dipole moments ionic complexes of transition, rare-earth and actinoid elements with an electric field of a double electric layer of the wall interface nanopores - solution. " The method is carried out by sequentially filling nanopores of a nanoporous electrically conductive material with a solution containing ionic complexes of transitional, and / or rare earth, and / or actinoid elements, displacing weakly localized ionic complexes of transitional, rare earth, and actinoid elements from nanopores.

The disadvantage of this method is the difficulty in implementing the proposed technological solutions on an industrial or enlarged laboratory scale.

A known method of isolation of gadolinium by extraction with organophosphorus compounds (patent No. RU 2518619, publ. 06/10/2014), including the extraction of terbium, dysprosium and heavier REE in the organic phase, washing and re-extraction in the first stage, characterized in that from the obtained raffinate solution at the second stage, gadolinium is extracted into the organic phase, leaving europium, samarium, neodymium and other cerium REEs in the aqueous phase. Gadolinium is recovered from the obtained organic phase into a reextract, the entire reextract containing gadolinium is returned to the washing stage and the process is carried out until the desired content of samarium and europium is reached in gadolinium, the resulting gadolinium solution is removed and the process is repeated again.

The disadvantage is the complexity of the proposed technological solutions in the washing stage of the reextract.

A known method of extracting rare earth metals (REM) from dilute aqueous acidic solutions (application for invention of the Russian Federation No. 2013109742, publ. 09/10/2014), comprising successive stages of liquid-phase extraction of REM into the organic phase and reextraction of REM from the organic phase, characterized in that reextraction is carried out by precipitation of rare-earth metals into the solid phase in the form of a sparingly soluble salt of a strong acid (pKa <0), extractants selected from the group consisting of phosphine oxide in kerosene, tributyl phosphate in kerosene, di- 2-ethylhexyl phosphoric acid (D2EGFK), a sparingly soluble salt of rare-earth metals are rare-earth sulfates.

The disadvantage of this method is that the re-extraction of rare-earth metals from the organic phase is carried out by precipitation of rare-earth metals into the solid phase in the form of a sparingly soluble sulfate salt.

A known method of extraction purification of nitrate solutions containing rare earth metals (REM) (RF patent No. 2517651, publ. 05/27/2014), including multi-stage countercurrent extraction of impurities from an aqueous nitric acid solution with tributyl phosphate (TBP), characterized in that the solution is purified with the concentration of REM 100-150 g / l, while 5 stages of extraction are carried out with the ratio of organic and aqueous phases O: B = 1: 1.1, after which 3-5 stages of washing with a ratio of O: B = 10: 1 and 5 are carried out steps of stripping in the system 100% TBP - aqueous solution p nitrate salts.

The disadvantage of this method is the multistage nature of the proposed technology, including the processes of cleaning, washing and re-extraction.

A known method of extracting rare earth metals from aqueous solutions (RF patent No. 2484163, publ. 03.04.2012), includes the extraction of rare earth metal cations with an organic phase containing an extractant solution in an inert diluent. As an extractant, naphthenic acid is used. Kerosene is used as an inert solvent. Extraction is carried out in three stages with a volume ratio of organic and aqueous phases O: B = 1: (9-11) at each stage. In this case, in the first stage, europium (III) cations are recovered with a content of 10-13 vol.% Naphthenic acid in kerosene and a pH of an aqueous solution of 5.0-5.1. At the second stage, samarium (III) cations are recovered at a content of 13–16 vol. % naphthenic acid in kerosene and the pH of the aqueous solution of 4.6-4.7. In the third stage, cerium (III) and lanthanum (III) cations are recovered at the same extractant content and pH 5.0-5.1.

The disadvantage of this method is the multi-stage process and low purity of the obtained solutions of individual REEs.

A known method of extracting rare-earth metals from dilute aqueous solutions (Izvestiya Akademii Nauk. Chemical series. No. 5. "Flotoextraction of cerium ions from dilute aqueous solutions, publ. 2012), adopted as a prototype, which is a combination of ion flotation and liquid extraction of cations rare earth metal organic phase. Sodium dodecyl sulfate is used as a collector. Iso-octyl alcohol is used as the organic phase. Flotoextraction of cerium cations is carried out for 2 hours at a ratio of volumes of organic and aqueous phases O: B = 1: 40.

The disadvantage of this method is the choice of the ratio of the organic phase to the aqueous and a narrow range of the pH region at which rare-earth metals are extracted.

The technical result of the invention is to increase the degree of extraction of holmium cations (III).

The technical result is achieved by the fact that isooctyl alcohol is used as the organic phase, and anionic surfactants of the anionic type sodium dodecyl sulfate are used as a collector in a concentration corresponding to the reaction stoichiometry:

But ⁺³ + 3NaDS = Ho (DS) ₃ + 3Na ⁺ ,

where But ⁺³ is holmium (III) cation,

NaDS - sodium dodecyl sulfate,

while flotation is carried out at a pH of from 5.3 to 9.5 and a ratio of organic and aqueous phases from 1/20 to 1/40.

The method is illustrated by the following drawing:

FIG. 1 - experimental dependence of the distribution coefficients of holmium (III) ions on the pH of aqueous solutions of salts during flotoextraction using sodium dodecyl sulfate.

The method is as follows.

A surface-active (surfactant) anionic substance is added to the aqueous solution of holmium (III) salt, stirred, the pH is adjusted from 5.3 to 9.5. As anionic type surfactants, sodium dodecyl sulfate is used, the concentration of which corresponds to the stoichiometry of this reaction. Flotoextraction is carried out for 120 minutes After the process of flotation, the solution is analyzed for the content of holmium (III) cations.

The method is illustrated by an example. Flotation is carried out in a column made in the form of a cylinder, the bottom of which was a Schott filter. Anionic surfactants, sodium dodecyl sulfate, were added to 200 ml of a solution of holmium (III) nitrate with a concentration of 0.001 mol / L. The aqueous solution was adjusted to the appropriate pH. The flotation process was carried out for 120 minutes. The solution remaining in the column was analyzed after a certain time interval for the content of holmium (III) cations. The ratio of organic phase to water is from 1/20 to 1/40.

In FIG. Figure 1 shows the experimental dependence of the distribution coefficients of holmium (III) ions on the pH of aqueous solutions of salts during photo-extraction using sodium dodecyl sulfate. The experiment showed that at pH = 7.5, the extraction of holmium (III) cations from solution reaches at least 98%.

Thus, the method allows to achieve an increase in the degree of extraction of holmium (III) from a solution of its salts.

Claims (1)

A method for extracting holmium (III) from aqueous phases, including flotoextraction using an organic phase and a collector, characterized in that isooctyl alcohol is used as the organic phase and anionic surfactant NaDS sodium collector is used as a collector in a concentration corresponding to stoichiometry reactions:

where Ho ³⁺ is the holmium (III) cation,
NaDS - sodium dodecyl sulfate,
HoDS - holmium dodecyl sulfate,
while flotation is carried out at a pH of from 5.3 to 9.5 and a ratio of organic and aqueous phases from 1/20 to 1/40.

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