RU2191744C2 - Method of processing phosphate stock into phosphoric acid and its salts - Google Patents

Abstract

FIELD: inorganic compounds technology. SUBSTANCE: phosphate stock comes into contact with pulped cationite at weight ratio phosphate/cationite/solution equal to 1:(3-10):(1-6). Phosphoric acid solution is poured off, cake separated from cationite, and the latter is regenerated by weak hydrochloric acid solution. Decomposition process is repeated until saturated phosphoric acid solution is obtained and salts isolated. Phosphate-to-cationite ratio in each decomposition stage is chosen in correspondence with volume capacity of cationite and such as to ensure liquid-to-solids ratio (5.0-0.5):1. All types of cationites can be used. EFFECT: enabled reuse of spent cationite- regeneration solutions. 5 tbl, 23 ex

Description

 The invention relates to a technology for producing phosphoric acid from phosphate raw materials of any quality and occurrence conditions.

 A known method of producing phosphoric acid, including the decomposition of various acids and their mixtures, firing and subsequent industrial applications (see. Journal of Chemical Industry, 1977, 7, p. 511).

The disadvantage of this method is that the method is associated with the processing of sulfuric acid at a temperature of 90-95 ^o C, the duration of the process, significant energy consumption and excess acids.

 A known method of producing phosphoric acid, including the decomposition of various acids and their mixtures and further purification of phosphoric acid from various impurities (see application Germany 3127900, CL 01 D 11/04, 1983).

 The reasons that impede the achievement of the technical result indicated below when using the known method include the fact that the method requires high energy consumption and introducing additional reagents into phosphoric acid for its purification.

 In addition, when using sulfuric acid and its mixture with other acids, a large number of dumps are formed - gypsum, which requires the organization of tailings for the hundreds of millions of tons that have accumulated to date and continue to form. Environmental measures are also required for the capture of exhaust harmful gases in the production of phosphoric acid using existing technologies.

 Closest to the proposed method is the processing of phosphate feedstock into phosphoric acid and its salts, including the decomposition of phosphates using cation exchangers in an aqueous medium, separation of cation exchange resin, cake and solution, regeneration of cation exchange resin (see Patent of Ukraine 1838282, class 05 05 11/12 , 1990). Adopted for the prototype.

In the known method of processing phosphate raw materials into fertilizers, phosphorus-containing poor raw materials are decomposed in an aqueous medium in the presence of sulfocationionite in H ⁺ form with a ratio of phosphate: cation exchange resin 1: 1: 2 and solid: liquid, T: W = 1: 0.75-2 , for 0.6-1.5 hours. In this case, weak solutions of 0.3-4.5% phosphoric acid, purified from calcium and other impurities, are obtained.

For reasons that impede the achievement of the following technical result when using the known method adopted for the prototype, is the use of one KU-2x8 cation exchanger, its ratio is selected for poor phosphate raw materials (12% ppm P ₂ O ₅ ), and the presented ratios T: W do not allow to obtain phosphoric acid solutions above 1-5% ppm P ₂ O ₅ . In addition, the specified method has not resolved the issue of disposal of solutions of cation exchange resin regeneration with its repeated use.

 The basis of the invention, “A method for processing phosphate raw materials into phosphoric acid and its salts,” is set the task by improving the known method - the use of various types of cation exchangers and the production of more concentrated solutions of phosphoric acid, as well as the disposal of cation exchange resin regeneration solutions.

 The problem is achieved in that in the method of processing phosphate raw materials into phosphoric acid and its salts, including the decomposition of phosphates using cation exchangers in an aqueous medium, separation of cation exchange resin, cake and solution, regeneration of cation exchange resin, the peculiarity is that the ratio of phosphate-cation exchange resin on each decomposition stages are taken in accordance with the exchange capacity of the cation exchanger; liquid to total solid, W: T = 5.0-0.5: 1, and the process is carried out with a ratio of phosphate-cation exchange resin-solution equal to 1: (3-10) :( 1-6).

Between the set of essential features set forth in the claims and the above technical result, there is the following causal relationship:
The claimed method of processing phosphate raw materials into phosphoric acid and its salts allows to obtain concentrated solutions of purified phosphoric acid and acid salts of calcium phosphates, where P ₂ About ₅ : CaO> 1.

 In this case, cation exchangers of various types are used, which allows the process to be carried out when choosing the optimal regime for a particular type of cation exchangers.

 A feature is that the method provides the disposal of solutions after regeneration of cation exchangers.

 The achievement of the following technical result in the implementation of the proposed method is possible in the presence of all the essential features, in the absence of one of them, the technical result cannot be achieved.

 Comparison of the proposed solution with the known shows that for the first time it was proposed to use a method that allows to obtain phosphoric acid using cation exchangers of various types and to carry out the process in the optimal mode for a particular type of cation exchange resin.

 Therefore, the claimed solution meets the criterion of "novelty."

 Each of these signs affects the technical result, and new values of these signs or their relationship could be obtained on the basis of known dependencies, patterns.

 Therefore, the claimed invention meets the criterion of "inventive step".

 The claimed method is as follows.

 A portion of phosphorite concentrate (of any quality and bedding conditions), finer than the size of cation exchangers (0.315-1.2 mm), is contacted in a water pulp with cation exchange resin (monofunctional, bifunctional or multifunctional) for 20-60 minutes. The amount of water ranges from 0.5 to 20 parts by volume with respect to the starting phosphorite. Then the solution is separated by decantation, centrifugation, and the cake is separated from the cation exchanger on a grid or on a concentration table, washing with either the resulting solution or with water. Cation exchanger regenerate 2-3 times with hydrochloric acid (5-10%) solution. The latter is wrapped again in the process.

 Phosphorus-containing raw materials from both Ukraine and Russia, as well as from Africa and Israel, were processed (see table 1).

 Specific conditions and results of the method are shown in tables.

 A common feature of all experiments is the mechanism of phosphorite decomposition, based on their heterogeneity, when using cation exchange dysfunction occurs in the phosphate-cation-water-water system, the cationic part (calcium and other isomorphic impurities) passes to the cation exchange resin, and the anionic part (mainly phosphorus oxide ) - into the water extract. Thus, in one contact step, the resulting phosphate solution is purified from impurities. This happens in accordance with the ionic potential of the ions entering the structure.

 Example 1. Bryansk phosphorites (metro Unecha) were contacted on a mechanical shaker with monofunctional cation exchange resin at a ratio of 1: 2.5 and T: W = 1: 2 for 30 minutes. The solution was decanted, the cake from the cation exchanger was separated on a 0.25 mm grid, washing with the same solution. The distribution of impurities is shown in table 2.

 From table 2 it is seen that the impurities are distributed between the cake and cation exchange resin, purifying the phosphorus solution. The extraction of ions to cation exchange resin is higher, the lower the ion potential.

 Example 2. Israeli phosphorites were mixed with cation exchange resin in accordance with the exchange capacity of monofunctional cation exchange resin, placed in a glass column (d: h = 1: 2), water was passed through, then a reverse phosphate solution. The quality of the obtained phosphoric acid for three cycles of turnover is shown in table 3 (paragraph 1).

Tunisian phosphorites are dangerous with a high cadmium content (more than 35 g / t), but, as can be seen from table 3 (p. 3), in phosphorus-saturated cadmium solutions - 6 • 10 ^-5 % ppm.

 Osykovsky phosphorites decompose by the proposed method with purification from iron and fluorine (see table 3, p. 2).

 Examples 3-15. Confirmation of the possibility of decomposition of phosphate raw materials of various origin using various cation exchangers (see table 4).

 It can be seen from the examples that both phosphorites of various deposits and apatites undergo decomposition using various types of cation exchangers (examples 11.15).

 The ratios of the phosphate product (P) to cation exchangers (K) differ from the prototype method, namely: for more complete extraction of phosphorus from cake, it is necessary to take cation exchange resin more than 200%, K: P> 2. This is due to the fact that in a poor phosphorus-containing product there is less calcium oxide, which is transferred to cation exchange resin, with an increase in the content of which the K: P ratio should increase, in accordance with the exchange capacity of the cation exchange resin.

 In addition, participation in the process of bi-and multifunctional cation exchangers allows you to immediately obtain phosphorus salts in which the content of calcium oxide is less than phosphorus (in example 10, the precipitate contains 42% ppm CaO, and in example 14 - CaO is 13.8% m .d.).

 From examples 3, 4, 7 it follows that washing the cation exchanger contributes to a greater transition of phosphorus into solution, which determines an increase in W: T> 2: 1. In addition, it is necessary for further circulation of the solution in order to saturate it, because part of the solution goes to wetting the starting products.

 The task posed also determines the choice of the hardware design of the process - it can be a countercurrent drum apparatus, a system of spiders or percolators.

 Examples 16-23. Justification of the choice of modes of the process (see table 5).

 In example 16, Unecha ore and monofunctional cation exchange resin were taken in a ratio of 1: 2.5. The calcium content of the cation exchange resin shows that the maximum capacity of 8.8%, i.e. 4.4 mEq / g. However, such a quantity of cation exchange resin is not enough for complete extraction of phosphorus into the solution and washing, since this value is (354.4 + 39.2) / 5 = 78.7% at each stage of the turnover. The amount of cation exchanger should be taken in a ratio stoichiometric to calcium oxide (29.8: 8.8), i.e. 3.4: 1.

 In example 17, the Novo-Amvrosievsky concentrate and bifunctional cation exchange resin participated. Its ratio of 3.8: 1 is sufficient for high extraction of phosphorus into the solution and wash water at each stage (754.3 + 44.6) / 8 = 99.8%.

 In examples 18, 19, where products with a high content of calcium oxide were taken, namely: in concentrates of the Mateyka CaO site - 49.3% ppm, and in Israeli CaO phosphorites - 49.05% ppm; the cation-product ratio should be more than 5: 1 (49: 8.8), which allows one to obtain high technological parameters for the extraction of phosphorus oxide into the solution and its concentration.

Examples 20, 21, 22 with the participation of concentrates of the Mateika site and various cation exchangers prove that the decomposition of phosphorites occurs without the participation of the liquid phase, the natural moisture of the cation exchangers (30-50%) is sufficient for calcium conversion to take place, and it is possible to suck out a phosphoric solution from cation exchange resin acids with a content of P ₂ O ₅ 10% ppm In cake, the yield of which does not exceed 15%, 1-6% of phosphorus pentoxide remains.

Example 23. In the process of percolation involved a concentrate of the Mateika site, monofunctional cation exchange resin and a solution after elution of calcium from cation exchange resin. The conditions of the saturated solution were chosen so that weights of phosphorite increased, but the volume of solutions and cation exchangers did not. As can be seen from example 23 of table 6, the ratio of phosphorus to calcium in solutions is everywhere more than 1, and the final concentration of phosphorus reaches 14.4%, which corresponds to 19% phosphoric acid. In addition, at the final stages of saturation of phosphoric acid, it self-purifies - precipitates containing up to 10% fluorine precipitate from the solution, according to X-ray diffraction analysis corresponding to the formula: Ca ₄ (AlSi) F ₆ ) (F-OH) SO ₄ • nН ₂ O , while in phosphoric acid the fluorine content does not exceed 0,00028% ppm. (7th, 9th turn).

 Apparently, calcium chloride (2% ppm) in solution is a good salting out agent for impurities, which further increases the value of the process, which is low-waste and environmentally friendly, because in the process, not only solutions of phosphoric acid are wrapped, but also solutions after the regeneration of cation exchangers are returned to the process of saturation with phosphorus.

 After vacuum evaporation, solutions of phosphoric acid were obtained with a density of d = 1.146-1.2-1.32, which corresponds to an acid content of 27-33-48%.

 Examples 24-28. Confirmation of the conditions for the formation of acid salts of calcium phosphates. According to X-ray diffraction analysis, a mixture of calcium mono- and diphosphates is formed, in which the calcium content is lower than phosphorus, and the release of acid phosphates occurs both from dilute and concentrated solutions (see table 7).

 The full chemical composition of monocalcium phosphate obtained from Israeli phosphorites upon saturation of phosphoric acid by percolation is presented in table 8.

Claims (1)

 A method of processing phosphate raw materials into phosphoric acid and its salts, including the decomposition of phosphates using cation exchangers in an aqueous medium, the separation of cation exchange resin, cake and solution, the regeneration of cation exchange resin, characterized in that the ratio of phosphate: cation exchange resin at each stage of decomposition is taken in accordance with the exchange capacity of cation exchange resin , liquid to total solid W: T = 5.0-0.5: 1, and the process is conducted with a ratio of phosphate: cation exchanger: solution equal to 1: (3-10) :( 1-6).

Images