Dissolution kinetics of kaolin mineral in acidic media for predicting optimal condition for alum production

Folahan A. Adekola; Alafara A. Baba; Sadisu Girigisu

doi:10.1007/s11771-017-3433-9

Journal of Central South University ›› 2017, Vol. 24 ›› Issue (2) :318 -324. DOI: 10.1007/s11771-017-3433-9

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Dissolution kinetics of kaolin mineral in acidic media for predicting optimal condition for alum production

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Abstract

The dissolution kinetics and mechanisms of reaction of Batagbon Kaolin in sulphuric and fluosilicic acids were studied. Leaching temperature, acid concentration, particle size, solid-to-liquid ratio, and stirring speed were selected as process parameters. It is observed that the dissolution rate increases with decreasing particle size and solid-to-liquid ratio, and increases with stirring speed, acid concentration, and leaching temperature. The experimental results indicate that the dissolution rate is of mixed control via hydrogen ion [H⁺] action, with reaction order of 0.813 and the reaction kinetics can be expressed as K_mt=[1-(1-x)1/3+y/6[(1-x)^1/3+ 1-2(1-x)^2/3]. The activation energy of the process is determined to be 21.6 kJ/mol. The level of the product quality is also evaluated.

Keywords

kaolin / alum / sulphuric and fluosilicic acid / leaching / kinetic model / mixed control

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Folahan A. Adekola, Alafara A. Baba, Sadisu Girigisu. Dissolution kinetics of kaolin mineral in acidic media for predicting optimal condition for alum production. Journal of Central South University, 2017, 24(2): 318-324 DOI:10.1007/s11771-017-3433-9

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References

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[1]	ConsidineG DVan NOSTRAND’S Encyclopedia of Chemistry [M], 2005LondonJohn Wiley and Sons, Inc.251-255

[2]	Industrial Project Report Alum. Aluminium sulphate [EB/OL] [2011–11-28]. http// www.scribd.com/doc.

[3]	IsmailA K. Energy saving during alum production from kaolin with coproduction of alumina-silica composites from process silica wastes [C]//. Proceedings of the XI International Seminar on Mineral Processing Technology, 2010781-787

[4]	FordK J R. Sulphuric acid and ammonium sulphate leaching of calcined clay [J]. Hydrometallurgy, 1992, 29: 109-130

[5]	PhilipsC V, WillsK J. Acid dissolution of alumina from waste aluminium [J]. Hydrometallurgy, 1982, 9: 15-28

[6]	ReginaO A, OkechukwuD O. Application of the shrinking core model to the analysis of alumina leaching from ukpor clay using nitric acid [J]. International Journal of Engineering Research & Technology (IJERT), 2012, 3(1): 1-13

[7]	GirigisuSProduction of alum from some local kaolin samples: leaching kinetics and process optimization [D], 2013

[8]	FanA, BrownR C, WheelockT D, CookerT A, MomuraM, ZhuangY. Production of a complex coagulant from fly ash [J]. Chemical Engineering Journal, 2005, 106: 269-277

[9]	AderemiB O. Kinetics study on aluminium alumination spent acid recovery process [J]. Nigeria Journal of Engineering, 2002, 10(10): 27-34

[10]	BabaA A, MasobalajeM A, IbrahimA S, GirigisuS, ElettaO A A, AlukoF I, AdekolaF A. Bleaching of a Nigerian kaolin by oxalic acid leaching [J]. Journal of Chemical Technology and Metallurgy, 2015, 50(5): 623-630

[11]	BabaA A, AsalaO A, BalogunA F, AyinlaK I, BaleR B, AdekolaF A, AlabiA G F. Treatment of a Nigerian kaolin ore for improved industrial applications [J]. Moroccan Journal of Chemistry, 2016, 4(1): 119-127

[12]	BabaA A, AdekolaF A, ArodolaO A, IbrahimL, GhoshM K, SheikA R. Simultaneous recovery of total iron and titanium from ilmenite ore by hydrometallurgical processing [J]. Metall Mater Eng, 2012, 18(1): 67-78

[13]	BabaA A, IbrahimA S, BaleR B. Purification of a Nigerian talc ore by acid leaching [J]. Applied Clay, 2015, 114: 476-483

[14]	TumakS, CiftilikA AKUIL. Factorial experiments for iron removal from kaolin by using single acid two-step leaching with sulphuric acid [J]. Hydrometallurgy, 2013, 134–135: 80-86

[15]	SultanaU K, GulshanA S W, KurnY. Kinetics of leaching of iron oxide in clay in oxalic acid and in hydrochloric acid solutions [J]. Materials Science and Metallurgy Engineering, 2014, 2(1): 5-10

[16]	LawrenceC, EdomwonyiO, BenjaminO A. Comparative study of alum production from Nigeria kaolin clay [J]. Materials Science and Technology Conference and Exhibition, 201116-20

[17]	Al-ZahranA A, Abdul-MajidM H. Extraction of alumina from clays by hydrochloric acid process [J]. JKAU: Eng Sci, 2009, 20(2): 29-41

[18]	DegerU MUSTAFA. Dissolution kinetics of iron and aluminium from red mud in sulphuric acid solution [J]. Indian Journal of Chemical Technology, 2007, 14(3): 263-268

[19]	LapidusG d, LourdesM M. The effect of product solubility on the leaching kinetics of non-porous minerals [J]. Hydrometallurgy, 1988, 20: 49-64

[20]	AydoganS, ArasA, CanbazogluM. Dissolution kinetics of sphalerite in acidic Ferric chloride leaching [J]. Chemical Engineering, 2005, 114: 67-72

[21]	HabashiF. Principles of Extractive Metallurgy [M]. New York: Gordon & Breach, 1980107-153

[22]	RayH S. Kinetics of Metallurgical Reactions [M]. New Delhi: Oxford and IBH Publishing, 199323-41

[23]	GökhanU. Kinetics of sphalerite dissolution by sodium chlorate in hydrochloric acid [J]. Hydrometallurgy, 2005, 95: 39-43

[24]	BabaA A, AdekolaA F, BaleR B. Development of a combined pyro-and hydro-metallurgical route to treat spent zinc-carbon batteries [J]. Journal of Hazardous Materials, 2009, 171: 838-84

[25]	BabaA A, AdekolaF A. Hydrometallurgical processing of a Nigerian sphalerite in hydrochloric acid: Characterization and dissolution kinetics [J]. Hydrometallurgy, 2010, 101: 69-75