Method of Processing and Treatment of Alunite Ores

Information

  • Patent Application
  • 20210071281
  • Publication Number
    20210071281
  • Date Filed
    January 22, 2019
    5 years ago
  • Date Published
    March 11, 2021
    3 years ago
  • Inventors
    • Tagijev; Elsad
    • Taghiyev; Eldar
    • Agajeva; Lale
Abstract
The alunite ore processing method consists of crushing, grinding and flotation of raw alunite ore. The enriched alunite ore is roasted at 520 to 620° C., the roasting time is 1 to 3 hours. The roasted alunite is leached with 5 to 20% sodium carbonate solution, which is in 100 to 110% of the stoichiometric amount required to bond the SO3 aluminum sulfate in the alunite with leaching conditions of 70-100° C. for 0.5-2.0 hours. The obtained slurry contains all of the potassium sulfate from the alunite and all of the sodium sulfate obtained from sodium carbonate. In the insoluble residue remains all aluminium oxide and residual rock. The sulfate solution is separated from the insoluble residue and is converted with potassium chloride to potassium sulphate (fertilizer) and kitchen salt. The insoluble residue is treated by the Bayer method without the use of an autoclave and results in aluminium oxide (alumina) and quartz sand.
Description
TECHNICAL FIELD

This invention relates to/concerns technology of alunite ore processing resulting in the production of γ-Al2O3 with the production of fertilizer potassium sulfate, kitchen salt, metallurgical aluminum oxide and quartz sand.


BACKGROUND ART

Alunite is a raw material for the aluminum and chemical industries. Industrial alunite ore deposits are common in the USA, China, Azerbaijan, Iran, Mexico, Kazakhstan, Ukraine, Russia and other countries. The presented invention concerns the processing of alunite ore with the production of fertilizer potassium sulphate, kitchen salt, metallurgical alumina and quartz sand.


An alkaline reduction method for processing alunite ore [1] is known. This method was used in the Ganja Aluminum Combine (GGC). Due to significant technological drawbacks (such as low alumina yield of less than 70 pollution of the environment by dust and gas, a need for rare and expensive raw materials, large quantities of solid waste from 5 tons per 1 ton of alumina and an undesirable by-product sulfuric acid) GGC ceased its operations in 1992 and to this date does not operate.


A method for processing of alunite ore was developed for the production of potassium fertilizers (SOP), sulfuric acid, alumina and quartz sand in Utah (USA) [2]. In this method, the alunite ore is roasted at 600° C. or lower with the release of SO2, which leads to the production of sulfuric acid, and the roasted alunite is extracted with hot water to produce K2SO4 (SOP). A reducing agent (excess oil or elemental sulfur vapors) should be introduced during roasting in order to acquire entire SO2 aluminium sulphate. The combustion temperature of 600° C. allows to preserve γ-Al2O3 in an active form. However, leaching (in hot water at 80 to 99° C.) of the alunite T≤600° C. results in the loss of SOPs due to the formation of water-insoluble basic salts. The yield of SOP in the solution does not exceed 65 to 70%. Roasting of the alunite at 800 to 900° C. improves SOP yield to almost 100%, while γ-Al2O3 is converted into an insoluble form of α-Al2O3. There is no floatation method that can divide α-Al2O3 and quartz the insoluble residue in order to obtain metallurgical alumina.


The drawbacks were eliminated by the potash-alkaline method (Liner-Taghiyev) [3, 4, 5, 7], where the alunite roasted at the temperature of T≤550° C. was leached with potassium carbonate solution according to the reaction:





K2SO4.Al2(SO4)3.2Al2O3+nn+3K2CO3=4K2SO4+3Al2O3+nn+3CO2(nn−waste rock).


Up to 4 times more SOP and alumina (γ-Al2O3) is transferred into the solution, the metallurgical-Al2O3 remains in the insoluble residue. The SOP is obtained from the solution and the insoluble residue is processed by the Bayer method by means of leaching with the recycled solution of aluminate at T=80-90° C. to obtain metallurgical alumina and quartz sand. The disadvantage of this method is the use of a rare and expensive (including USA) potassium carbonate.


The foregoing drawbacks are addressed by the invention below.


The state of the art is further described in the following literature:

  • 1. G. V. Labutin Recovery method for the processing of alunite. Autor. Svid. USSR No. 9911 a No. 108947 from year 1948.
  • 2. Internet. Potash Ridge Corp. Technical report. Dated 24 Apr. 2017 Project No. 17M16.
  • 3. A. I. Liner, V. I. Zakharova, Yu. A. Layner, El Taghiyev, Z. Pevzner Autor. Svid. SSSR No. 460709 d. 21 Oct. 1974.
  • 4. E. I. Tagijev, patent of the Republic of Azerbaijan I 2001 0142 dated 2 Oct. 2001.
  • 5. E. I. Tagijev, patent of the Republic of Azerbaijan I 2003 0210 dated 30 Oct. 2003.
  • 6. E. I. Tagijev, I. S. Babayev, S. B. Rajabli, A. T. Khudiev, T. B. Aliyev Autofi. Svid. SSSR 5 No. 872456 dated 15 Jun. 1981.
  • 7. E. I. Tagijev, Technology Of Complex Waste-fee Processing Of Alunite Ores. Baku, Elm, 2006, 504 pages (research monograph in Russian).


SUMMARY OF THE INVENTION

The processing of the alunite ore (alunite) consists first of the known steps: crushing, grinding and flotation of alunite ore. Flotation of the alunite ore proceeds with a flotoreagent and is proposed in the method according to the state of the art, point 2. The enriched alunite ore containing 25-95% preferably 60% of mineral alunite is further roasted at a temperature of 520 to 620° C., the roasting time is 1 to 3 hours. The roasted alunite, in accordance with the present invention, is further leached with 5 to 20% sodium carbonate solution, which is added in an amount of 100 to 110% of the stoichiometric amount required to bond the SO3 aluminium sulphate in the alunite, that is Na2CO3 is added in an excess of 0 to 10% over the calculated stoichiometric coefficients of the reaction equation 1, at 70-100° C. for 0.5 to 2.0 hours. The obtained slurry solution contains all potassium sulphate from alunite and sodium sulphate obtained from sodium carbonate. In the insoluble residue remains all of aluminium oxide from alunite and waste rock, where the waste rock is silica-SiO2 and clay (aluminum) aluminosilicate. The sulfate solution is further separated by either filtration or precipitation from an insoluble residue and is converted with potassium chloride to potassium sulphate (fertilizer) and kitchen salt. The insoluble residue is processed by the Bayer method without autoclaving and at a temperature of less than 100° C. to form aluminium oxide (alumina) and quartz sand.


In order to overcome the disadvantages of the prior art, it is proposed to replace the solution of potassium carbonate with a solution of calcined soda (1) and then to convert right after the first leaching the obtained sodium sulphate by the conversion method with KCl to potassium sulphate (fertilizer) and sodium chloride NaCl (2), which is the basic/fundamental inventive idea of this invention.





K2SO4.Al2(SO4)3.2Al2O3+nn+3Na2CO3=K2SO4+3Na2SO4+3Al2O3+nn+3CO2  Reaction (1):





K2SO4+3Na2SO4+6KCl=4K2SO4+6NaCl,  Reaction (2):


3Al2O3+nn is the insoluble residue, which is processed by the Bayer method without autoclaving to form aluminium oxide (alumina) and quartz sand. Alunite is roasted at 520 to 620° C., the time of roasting is 1 to 3 hours.


The roasted alunite is leached with 5 to 20% sodium carbonate solution in an amount of 100 to 110% of the stoichiometric amount required to bond the SO3 aluminium sulphate in the alunite, that is Na2CO3 is added in an excess of 0 to 10% over the calculated stoichiometric coefficients of the reaction equation at 70 to 100° C. for 0.5 to 2.0 hours.


The products of this process are: K2SO4— fertilizer, NaCl—kitchen salt, Al2O3— metallurgical, SiO2— quartz sand and coagulant for water purification [6].


Note: The United States is the second largest producer of sodium carbonate in the world, and Canada is the world's largest producer of potassium chloride (KCl).







EXAMPLES OF EMBODIMENTS OF THE INVENTION
Example 1

We take an alunite ore with an alunite content of 60% by weight, with the following composition, % by weight:




















K2O
Al2O3
SO3
H2O
nn
Σ









6.82
22.17
23.18
7.82
40
99.9










100 g of alunite (alumina) is crushed. Alunite (alunite ore) is further grinded, after the flotation enrichment it is roasted in an oven at T=550° C. for 1 hour and then leached in the solution of Na2CO3.


A sodium salt solution is prepared: 22.2 g of Na2CO3 is dissolved in 350 ml of water, the amount of soda is 105% wt. from stoichiometric. The leaching time is 1.5 hours at Tleach 90° C.


Into solution are transferred: K2O—99% by weight; Na2CO3-100% by weight; Al2O3— 0.5% wt.; SO3—9 8% wt. or K2O=6.8 g, Na2O=13 g, SO3=2.3 g, Al2O3=0.1 g.


In the insoluble residue remains 62.2 g. CO2 gas is formed.


The suspension is filtered and washed.


The filtrate with the washing water is evaporated.


We obtain a mixture of sulphates K, Na, where the sulphate K is 12.5 g, Na sulphate—29.8 g, the total of 42.3 g of the mixture. This is a mixture of sulphates obtained from the evaporated mixture of the filtrate and washed water.


It is required 23.7 g of KCl to produce 29.8 g of Na2SO4. This is reaction number 2: K2SO4+3Na2SO4+6KCl=4K2SO4+6NaCl, with K2SO4 already present in the alunite in the amount of 12.5 g.


The result is 36.6 g of K2SO4 plus 12.5 g of K2SO4 from alunite. Total of 49 g of K2SO4 and NaCl of 16.8 g.


Example 2

The method of treating the alunite ore consists of the following steps:

    • 1. The alunite ore from the mine is crushed resulting in particles of 10 to 20 mm in size.
    • 2. Followed by wet milling with a resulting particle size of the resulting powder under 0.074 micron (passed through a 200 mesh).
    • 3. Enrichment of the ground alunite ore by means of flotation. The resulting weight of the enriched ore containing 60% of alunite is 5.02 t.
    • 4. Drying and roasting of the enriched alunite ore from step 3 at 530 to 550° C. for one hour. After drying and roasting, the weight of alunite ore is 4.63 tons.
    • 5. A solution from 1.12 t of Na2CO3 (100%) is prepared, the solution is prepared in a 5% excess over the stoichiometric balance of equation (1).





K2SO4.Al2(SO4)3.2Al2O3+waste rock+3Na2CO3=K2SO4+3Na2SO4+3Al2O3+waste rock+3CO2,  (1)


where 3Al2O3+waste rock is the insoluble residue. The waste rock contains silica, silica sand (SiO2) and aluminosilicate (alumosilicate).

    • 6. The enriched alunite ore, after drying and roasting from step 4, is leached in a solution of Na2CO3 prepared according to step 5 for 1.5 hours at 90° C. in the course of the reaction (1).
    • 7. The slurry suspension from leaching (step 6) is filtered and the filter cake is washed. 2.133 t of solution for evaporation is formed (mother liquors containing Na2SO4 and K2SO4 and an insoluble residue).
    • 8. The water after the washing of the cake can be used to prepare the solution of Na2CO3. The mother liquors from step 7 are evaporated/concentrated and converted according to the reaction (2) to K2SO4 fertilizer (2.47 t) and kitchen salt NaCl (0.845 t).





K2SO4+3Na2SO4+6KCl=4K2SO4+6NaCl  (2)


1.19 t of KCl is used for the conversion.

    • 9. The insoluble residue from step 5 (3Al2O3+waste rock) is processed by the Bayer method according to the reaction (3) without using an autoclave at a temperature below 100° C. 0.05 t of NaOH and the working solution are introduced into the reaction.





Al2O3+2NaOH=2NaAlO2+H2O.  (3)


Aluminium oxide (alumina) is formed and remains unchanged “waste rock”, i.e. silica sand (SiO2) and aluminosilicate.

    • 10. The products from step 9 are hydroseparated into the sand fraction and the clay fraction (aluminosilicate and alumina).
    • 11. The clay fraction from step 10 is precipitated and the filter cake is rinsed, with the formation of sludge in the sediment and the supernatant.
    • 12. The sand fraction is washed and filtered to form the silica sand (2.0 t) and the filtrate.
    • 13. The filtrate after filtration of the sand from step 12 and the supernatant after precipitation of the clay fraction from step 11 are combined. Thusly formed solution undergoes desilication to form a white sludge and aluminate solution (supernatant).
    • 14. A reaction of the white sludge with H2SO4 (0.05 t) gives the coagulant from the white sludge (0.33 t).
    • 15. The solution of aluminates resulting from the desilication from step 13 is further decomposed to form Al(OH)3 and the mother liquor. The mother liquor may be further evaporated to form a working solution which may enter step 9 (re-concentration and recycling of water).


16. One ton of γ-Al2O3 is formed by calcination of Al(OH)3.


BRIEF DESCRIPTION OF DRAWINGS

Diagram in FIG. 1 shows the method for processing and treating of alunite ores.


ADVANTAGES OF THE INVENTION OVER THE PRIOR ART





    • Production of metallurgical aluminium oxide (alumina, Al2O3) reaches 90

    • The amount of SOP produced is increased 4 times, with a yield of 90%.

    • Procedures that pollute the environment with dust and gas (SO2) are eliminated.

    • There is no need to use precious and expensive raw materials.

    • This method is in fact free of solid waste.

    • In addition to the efficient production of metallurgical aluminite and SOP, this method allows to simultaneously produce other products: kitchen salt, quartz sand and coagulant for cleaning potable and industrial water.





INDUSTRIAL APPLICABILITY

According to the present invention, the method for the treatment of alunite is used to treat alunite ores with the production of Al2O3, as well as potassium sulphate, quartz sand, utility and potable water purification coagulant and kitchen salt as a by-product.

Claims
  • 1. Process for the treatment of alunite ores comprises the following steps: crushing of alunite ore,grinding the alunite ore,enrichment of the alunite ore by flotation to the content of at least 50% of alunite by weight,roasting at 520 to 620° C. for 1 to 3 hours,preparation of a sodium carbonate solution, which is later used in a leaching process characterized in that the sodium carbonate solution comprises 5 to 20% sodium carbonate solution and is added to the alunite ore in a quantity of 100 to 110% of the stoichiometric amount required to bond the SO3 to the aluminum sulphate in the alunite ore, thereby forming a sodium sulphite solution,separation of the sodium sulphate solution from an insoluble residue,conversion of the sodium sulphate with KCl to potassium sulphate and sodium chloride to form a suspension,filtration and washing of the suspension to form a filtrate and washing water,evaporation of the filtrate and of the washing water, andtreating the insoluble residue by the Bayer method without the use of an autoclave to form a product comprising aluminium oxide (alumina) and quartz sand.
  • 2. The process of the treatment of alunite ores according to claim 1, characterized in that the solution of Na2CO3 is prepared in a 5% excess over the stoichiometric balance of the following equation: Al2(SO4)3.2Al2O3+waste rock+3Na2CO3=K2SO4+3Na2SO4+3Al2O3+waste rock+3CO2, where 3Al2O3+waste rock is the insoluble residue and comprises one or more of silica, silica sand (SiO2) and aluminosilicate.
  • 3. The process of the treatment of alunite ores according to claim 1, characterized in that the leaching is carried out at a temperature of 70 to 100° C. tor 0.5 to 2.0 hours during the course of a reaction characterized by the equation according to claim 2.
  • 4. The process of the treatment of alunite ores according to claim 3, characterized in that the Bayer method without the use of an autoclave takes place with NaOH at a temperature below 100° C.
  • 5. The process of the treatment of alunite ores according to claim 4, characterized in that the product from the Bayer method is processed by hydroseparation to produce a sand fraction comprising aluminosilicate and a clay fraction comprising γ-Al2O3.
  • 6. The process of the treatment of alunite ores according to claim 5, characterized in that the clay fraction is precipitated to form a cake, which is washed, thereby forming a sludge in a resulting sediment and a resulting supernatant.
  • 7. The process of the treatment of alunite ores according to claim 6, characterized in that the sand fraction formed by the hydroseparation is washed and filtered to produce silica sand and a filtrate.
  • 8. The process of the treatment of alunite ores according to claim 7, characterized in that the filtrate after the filtration of the sand fraction and the supernatant after the precipitation of the clay fraction are combined and to form a solution, which undergoes desilication to form a white sludge and an aluminate solution.
  • 9. The process of the treatment of alunite ores according to claim 8, characterized in that a reaction of the white sludge with sulfuric acid results in the formation of a coagulant.
  • 10. The process of the treatment of alunite ores according to claim 8, characterized in dial the supernatant formed from desilication is decomposed to form Al(OH)3 and a mother liquor, which is further evaporated to form a working solution which is used as a starting reagent in a second Bayer method reaction (re-concentration and recycling of water).
  • 11. The process of the treatment of alunite ores according to claim 10, characterized in that metallurgical γ-Al2O3 is formed by the calcination of Al(OH)3.
  • 12. The use of sodium carbonate Na2CO3 in the leaching process according to claim 1 for the treatment of alunite ores and the production of one or more of aluminium oxide potassium sulphate, quartz sand, coagulant for the purification of utility and potable water and kitchen salt.
Priority Claims (1)
Number Date Country Kind
PV 2018-45 Jan 2018 CZ national
PCT Information
Filing Document Filing Date Country Kind
PCT/CZ2019/000004 1/22/2019 WO 00