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Preparation of potassium carbonate from insoluble potash ores: With 13X molecular sieve as a byproduct

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ã€Authorã€‘ MA Hong-wen, BAI Zhi-min, YANG Jing, WANG Ying-bin, QI Hong-bin, BAI Feng, ZHANG Xi-huanNational Laboratory of Mineral Materials, China University of Geosciences, Beijing 100083, China

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ã€Abstractã€‘ Insoluble potash ores of different types from nine representative localities are characterized by potassium feldspar as major mineral phase enriched in potassium. By pretreating the ores with such a procedure as ore crushing, bed sorting, wet magnetic sorting, and iron removing by acid leaching, potassium feldspar powders with purity as high as 75% to 95% were prepared first in this research. Then, with sodium carbonate as an additive, the powders were calcinated at 760⁸60 â„ƒ, leading to thermally decomposition of potassium feldspar to form a mixture of sodium metasilicate and sodium ï¼ˆpotassiumï¼‰ metaluminate, from which 13X type molecular sieve was hydrothermally synthesized. The physicochemical properties of the product are as good as those of its industrial analogues. The liquors filtered from the synthesized zeolites were rich in K⁺, Na⁺, and \[SiO₂ï¼ˆOHï¼‰₂\]^2- ions. By introducing CO₂ gas into the liquids, metasilicic acid precipitants were formed, which were further calcinated at around 250 â„ƒ for 2hrs to form precipitated silica. The residual liquors were then water-salt solutions in the ternary system of NaHCO₃-KHCO₃-H₂O. By evaporation, crystallization of NaHCO₃, separation from the liquids, and then evaporating the residual liquors, and crystallization of KHCO₃, both of precipitants were separated owing to much smaller solubility of the former, and at last, by calcinating the precipitants at 200 â„ƒ for 2hrs, both of sodium carbonate and potassium carbonate were prepared. The precipitated silica and potassium carbonate products well satisfy the Chinaâ€™s Chemical Industrial standard HG/T 2690-95 and the Chinaâ€™s National Standard GB 1587-2000 respectively. In such a way, the components of K₂O, Al₂O₃, and SiO₂ in potassium feldspar of the ores are all manufactured to valuable chemical products, giving rise to nearly 100% output coefficient of the potassium feldspar resources, close to zero discharge of solid wastes, wastewaters, and exhaust gases. The technique is a â€œgreen processâ€, characterized by energy conservation, high efficiency, and clean production. It is therefore feasible to be industrialized both in economic benefits and in environmental kindness.æ›´å¤š è¿˜åŽŸ

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ã€Key wordsã€‘ potassium feldsparï¼› 13X type molecular sieveï¼› precipitated silicaï¼› potassium carbonateï¼› green processingï¼›

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Preparation of potassium carbonate from insoluble potash ores: With 13X molecular sieve as a byproduct

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