RU2186865C2 - Recovery of molybdenum from aqueous tungstate solutions - Google Patents

Abstract

FIELD: hydrometallurgy. SUBSTANCE: process of recovering molybdenum from concentrated aqueous tungstate solutions involves preparation of acid solution by adding hydrogen peroxide and then hydrochloric acid to solution, followed by extraction of molybdenum with solution of trialkylamine and isooctyl alcohol in kerosene. EFFECT: reduced consumption of reagents. 10 tbl, 5 ex

Description

 The method of extracting molybdenum from aqueous solutions of tungstate relates to the extraction of substances by extraction and selective precipitation from an aqueous solution and can be used in non-ferrous and ferrous metallurgy, as well as in the treatment of industrial and domestic wastewater.

 A known method of purification of aqueous solutions of tungstates by precipitation of sparingly soluble molybdenum trisulfide, based on the difference in the conditions of formation and stability constants of molybdenum and tungsten sulfosalts [Zslikman AN University News. Non-ferrous metallurgy. 1979. 3. S. 97-103].

 The disadvantages of the method are the allocation of hydrogen sulfide during the deposition of molybdenum trisulfide, which requires the cost of neutralizing gases, the need for heating the solution, while the method does not provide deep cleaning.

 The closest technical solution is a method for extracting molybdenum from concentrated aqueous solutions of tungstate, including the preparation of an acid solution by introducing hydrogen peroxide and acid into the initial solution, extraction of molybdenum and subsequent precipitation of tungsten acid from raffinate [US 4275039, cl. C 01 G 39/00 of 06/23/1981].

 The disadvantages of the method are the high consumption of reagents, as well as the use of expensive and inaccessible extractants.

 The objective of the invention is to extract molybdenum from concentrated aqueous solutions of tungstate using an inexpensive and readily available extractant, as well as to reduce the consumption of reagents.

 The technical result that can be obtained by carrying out the invention is the cost-effectiveness and efficiency of the process of removing molybdenum from concentrated aqueous solutions of tungstate by extraction, in the formation of a dense, easily filtered sediment of tungsten acid with a low molybdenum content.

 This technical result is achieved in that in the known method for the extraction of molybdenum from concentrated aqueous solutions of tungstate, including the preparation of an acidic solution by introducing hydrogen peroxide and acid into the initial solution, the extraction of molybdenum and the subsequent precipitation of tungsten acid from the raffinate, the solution is prepared by first introducing the peroxide before extraction hydrogen, and then hydrochloric acid, and the extraction is carried out with a solution of trialkylamine and isooctyl alcohol in kerosene.

 The essence of the method is illustrated in table. 6-10, which give the results of the extraction of molybdenum from concentrated aqueous solutions of tungstate by extraction with a solution of trialkylamine and isooctyl alcohol in kerosene and subsequent precipitation from tungsten acid raffinate.

 Examples of specific performance of the method.

 Example 1 (table. 6).

An initial solution with a volume of 70 cm ³ containing 120 g / dm ³ W (VI) and 1.2 g / dm ³ Mo (VI) (weight ratio Mo (VI): W (VI) = 1: 100) was prepared by dissolving the salts Na ₂ WO ₄ • 2H ₂ O and Na ₂ MoO ₄ • 2H ₂ O in distilled water. First, a 36% peroxide solution was added to the resulting solution to a molar ratio of H ₂ O ₂ : (W + Mo) = 1.75: 1, then concentrated hydrochloric acid to pH 0, molybdenum was extracted from the resulting solution at pH 0 and an extractant volume of 35 cm ³ (extractant composition, wt.%: Trialkylamine - 8, isooctyl alcohol - 15, kerosene - the rest), tungsten acid was precipitated from raffinate at pH 0. The content of W (VI) and Mo (VI) in the initial solution, raffinate and clarified aqueous phase after deposition of tungsten acid was determined by weight and photocolorimetric methods on tokolorimetre mark CK-3. The content of components in the extract was determined but the difference between the concentrations of the components in the initial solution and in the raffinate. The pH of the solution was measured with a pH meter of pH-121 grade.

The extraction results are presented in table. 6, which shows the extraction time τ, min, the concentration of molybdenum and tungsten ions in raffinate C, mg / dm ³ distribution coefficient D, as the ratio of the concentrations of components in the extract and raffinate, the separation coefficient β, as the ratio of the distribution coefficients of molybdenum and tungsten, extraction ε,% wt.

From the data table. 6, we can draw the following conclusions:
1. During 30 minutes of extraction, the molybdenum content decreases from 1.204 to 0.224 g / dm ^3; subsequently, the molybdenum content slightly increases and by 2 hours of extraction is 0.260 g / dm ³ .

 2. Within 2 hours of extraction, the tungsten content in the solution is reduced by 31.4%.

 3. During the extraction process, the mass ratio of Mo: (Mo + W) in the solution decreases from 0.89 to 0.23%.

4. The best indicators of extraction obtained after 30 minutes of extraction and are: D _Mo = 8.75; β = 11.36; Mo / (Mo + W) = 0.23%.

 5. By increasing the number of extraction operations, it is possible to achieve the required degree of purification of tungsten from a molybdenum impurity.

 After 2 hours of extraction, the extract was separated from the raffinate, in the latter tungsten acid was precipitated. In the process of deposition of tungsten acid, molybdenum removal continues (see table 1).

 The rate of clarification of tungsten acid during its deposition from the raffinate is characterized by the performance of table 2.

 Thus, in less than a day, 97% of tungsten acid is precipitated, and subsequently the sediment becomes denser: after two days, the precipitate is compacted by 8.8% compared with the precipitate obtained after a day of deposition.

 The resulting precipitate is well filtered and washed.

 Example 2 (table. 7).

The extraction of molybdenum from an aqueous solution of tungstate was carried out analogously to example 1 with the only difference that the process was carried out using a smaller amount of peroxide at a molar ratio of H ₂ O ₂ : (W + Mo) = 1: 1.

From the data table. 7, we can draw the following conclusions:
1. During 45 minutes of extraction, the molybdenum content decreases from 0.912 to 0.272 g / dm ³ , subsequently the molybdenum content slightly increases and by 2 hours of extraction is 0.310 g / dm.

 2. Within 2 hours of extraction, the tungsten content in the solution is reduced by 15.7%.

 3. During the extraction process, the mass ratio of Mo: (Mo + W) in the solution decreases from 0.86 to 0.35%.

4. The best indicators of extraction were obtained after 45 minutes of extraction and are: D _Mo = 4.71; β = 13.85; Mo / (Mo + W) = 0.30%.

 5. By increasing the number of extraction operations, it is possible to achieve the required degree of purification of tungsten from a molybdenum impurity.

 After 2 hours of extraction, the extract was separated from the raffinate, in the latter tungsten acid was precipitated. During the deposition of tungsten acid, molybdenum removal continues (see table 3).

 The resulting precipitate is well filtered and washed.

 Compared with example 1, all indicators of extraction and subsequent precipitation of tungsten acid slightly deteriorated.

 Example 3 (table. 8).

The extraction of molybdenum from an aqueous solution of tungstate was carried out analogously to example 1 with the only difference that the process was carried out using more peroxide at a molar ratio of H ₂ O ₂ : (W + Mo) = 2.5: 1.

From the data table. 8, we can draw the following conclusions:
1. During 30 minutes of extraction, the molybdenum content decreases from 0.890 to 0.400 g / dm ³ , and subsequently a precipitate precipitates from the raffinate.

 2. During 15 minutes of extraction, the tungsten content is reduced by 30.7%.

 3. During the extraction process, the mass ratio of Mo: (Mo + W) in the solution decreases from 0.86 to 0.58%.

 The resulting precipitate is well filtered and washed.

 Compared with example 1, the rate of formation of tungsten acid in the raffinate increases sharply, a precipitate forms after 30 minutes of extraction. Within 15 minutes, the extraction indicators are similar to those presented in example 1.

 Example 4 (table. 9).

The extraction of molybdenum from an aqueous solution of tungstate was carried out analogously to example 1 with the only difference that the process was carried out at a higher concentration of molybdenum (VI) of 5.0 g / dm ³ (weight ratio Mo (VI): W (VI) = 1: 24 )

From the data table. 9, we can draw the following conclusions:
1. During 15 minutes of extraction, the molybdenum content decreases from 3950 to 2270 g / DM ³ .

 2. During 15 minutes of extraction, the tungsten content is reduced by 19.4%.

 3. During the extraction process for 15 minutes, the mass ratio of Mo: (Mo + W) in the solution decreases from 3.27 to 2.58%.

 4. There is an optimal extraction time (15 min) at which the separation indicators are maximum.

 After 30 minutes of extraction, the extract was separated from the raffinate, in the latter tungsten acid was precipitated. In the process of deposition of tungsten acid, molybdenum removal continues (see table 4).

 For less than 3 hours, the best results were obtained on the purification of sludge from molybdenum when extracting tungsten to a precipitate of more than 95%.

 The rate of clarification of tungsten acid during its deposition from the raffinate is characterized by the following indicators (see table 5).

 Over a period of less than 1.5-3.0 hours, more than 95% of tungsten acid is precipitated; subsequently, the volume of precipitated precipitate increases slightly.

 The resulting precipitate is well filtered and washed.

 Compared with example 1, the best indicators of extraction and precipitation were obtained at the initial time.

 Example 5 (table. 10).

 The extraction of molybdenum from an aqueous solution of tungstate was carried out analogously to example 1 with the only difference that the process was carried out without the use of peroxide.

 From the data table. 10 it follows that the extraction of molybdenum and tungsten is negligible, the separation of these components practically does not occur.

 After two hours of extraction, the raffinate was separated from the extract.

 The raffinate was a cloudy, colloidal solution from which no precipitate formed within two days.

 The process is inefficient.

 Experimental data indicate that the best extraction indices were obtained in Example 1. Tungsten acid precipitates were obtained containing not more than 0.04% molybdenum during the extraction of tungsten acid in one operation in the extraction and precipitation processes of at least 70%.

 Extraction with peroxide and subsequent precipitation of tungsten acid from the raffinate contributes to the production of a tungsten acid precipitate with a low content of molybdenum impurity, while the deposition rate of tungsten acid is high.

 The obtained precipitate of tungsten acid after washing can be used to obtain ammonium anhydride or paratungstate according to the usual scheme.

The clarified aqueous phase obtained after the precipitation of tungsten acid is a 1 M hydrochloric acid solution containing a certain amount of peroxide. Such a solution can be used in technological processes, in the treatment of wastewater from organic components, in the oxidation of gaseous components, for the oxidation of metal ions (Fe ²⁺ Cu ²⁺ , etc.) and for other purposes.

 The extract can be processed in the usual way.

 In combination with the optimal number of extraction operations and deposition cycles of tungsten acid according to the proposed technology, it is possible to carry out deep cleaning of tungsten from molybdenum impurities.

 The optimal consumption of peroxide and the ratio of the aqueous phase to the organic one is determined by the stoichiometry of the complexation reaction in the extract phase, the deposition rate of tungsten acid, temperature, the initial concentration of the solution components, the ionic strength of the solution, the molar ratio of molybdenum and tungsten ions in the solution, the pH of the solution, and other factors.

 The method is all the more effective the higher the concentration of tungsten ions and the lower the concentration of molybdenum ions in the initial solution being purified. The proposed method can be used for the decomposition of scheelite concentrates with acids.

 Compared with the prototype, the proposed method is more universal, reduces the consumption of extractant and other reagents, reduces the number of redistributions, allows you to get a dense, well filtered, precipitate of tungsten acid with the required degree of purification from molybdenum impurities, and the precipitated acid can be used to obtain anhydride or paratungstate according to the usual scheme.

Claims (1)

 The method of extraction of molybdenum from concentrated aqueous solutions of tungstate, including the preparation of an acid solution by introducing hydrogen peroxide and acid into the initial solution, extraction of molybdenum and subsequent precipitation from tungsten acid raffinate, characterized in that the solution is prepared before extraction by first introducing hydrogen peroxide and then hydrochloric acid, and the extraction is carried out with a solution of trialkylamine and isooctyl alcohol in kerosene.

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