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Application of Box—Behnken Design to Modeling the Effect of Smectite Content on Swelling to Hydrocyclone Processing of Bentonites with Various Geologic Properties

Published online by Cambridge University Press:  01 January 2024

Selçuk Özgen*
Affiliation:
Department of Mining Engineering, Afyon Kocatepe University, 03200 Afyonkarahisar, Turkey
Ahmet Yildiz
Affiliation:
Department of Mining Engineering, Afyon Kocatepe University, 03200 Afyonkarahisar, Turkey
*
* E-mail address of corresponding author: sozgen@aku.edu.tr
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Abstract

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As advances in technology have led to increased use of bentonites, more high-quality bentonite has been sought. The volume of high-quality bentonites available is shrinking and use of bentonite reserves containing impurities is inevitable. The aim of this study was to apply Box–Behnken experimental design and response surface methodology to model and optimize some operational parameters of a hydrocyclone to produce three groups of bentonite concentrates. The four significant operational parameters of hydrocyclones are feed solid ratio, inlet pressure, vortex diameter, and apex diameter, and these parameters were varied and the results evaluated using the Box–Behnken factorial design. In order to produce bentonite concentrates using a hydrocyclone, mathematical model equations were derived by computer simulation programming applying a least-squares method, using Minitab 15. Second-order response functions were produced for the swelling and to establish the quantity of smectite in the bentonite concentrates. Predicted values were found to be in good agreement with the experimental values (R2 values of between 0.829 and 0.999 for smectite and three different swelling groups for the bentonites). Although in natural states these bentonites are not suitable for industrial use, enhancements were obtained giving up to 81.45% smectite and by increasing swelling by 194% for the three bentonite groups. The swelling properties of the bentonites are improved by increasing the proportion of smectite content. The graphics were designed to relate swelling and smectite content according to the two-dimensional hydrocyclone factors, and each factor was evaluated in itself. The present study revealed that the Box–Behnken and response surface methodology can be applied efficiently to model the hydrocyclone for bentonite; the method is economical and provides the maximum amount of information in a short period of time and with the smallest numberof experiments.

Type
Article
Copyright
Copyright © The Clay Minerals Society 2010

References

Adams, J.M., 1987 Synthetic organic chemistry using pillared cation exchanged and acid treated montmorillonite catalysis: a review Applied Clay Science 2 309342.CrossRefGoogle Scholar
Allo, W.A. and Murray, H.H., 2004 Mineralogy, chemistry and potential applications of a white bentonite in San Juan province Applied Clay Science 25 237243.CrossRefGoogle Scholar
Alther, G.R., 1986 The effect of the exchangeable cations on the physico-chemical properties of Wyoming bentonites Applied Clay Science 1 273284.CrossRefGoogle Scholar
Aslan, N. and Cebeci, Y., 2007 Application of Box—Behnken design and response surface methodology for modeling of some Turkish coals Fuel 86 9097.CrossRefGoogle Scholar
Aslan, N., 2007 Application of response surface methodology and central composite rotatable design for modeling the influence of some operating variables of a Multi-Gravity Separator for coal cleaning Fuel 86 769776.CrossRefGoogle Scholar
Aslan, N., 2007 Modeling and optimization of Multi-Gravity Separator to produce celestite concentrate Powder Technology 174 127133.CrossRefGoogle Scholar
ASTM D 5890-95. Standard test method for swell index of clay mineral component of geosynthetic clay liners. American Society for Testing and Materials.Google Scholar
Barrer, R.M., 1989 Shape-selective sorbents based on clay minerals: a review Clays and Clay Minerals 37 385395.CrossRefGoogle Scholar
Biscaye, P.E., 1965 Mineralogy and sedimentation of recent deep sea clay in the Atlantic Ocean and adjacent seas and oceans The Geological Society of America Bulletin 76 803832.CrossRefGoogle Scholar
Box, G.E.P. and Behnken, D.W., 1960 Some new three level designs for the study of quantitative variables Technometrics 2 455475.CrossRefGoogle Scholar
Box, G.E.P. and Wilson, K.B., 1951 On the experimental attainment of optimum conditions Journal of the Royal Statistical Society B13 145.Google Scholar
Box, G.E.P. Hunter, W.G. and Hunter, J.S., 1978 Statistics for Experimenters: an Introduction to Design, Data Analysis, and Model Building New York John Wiley and Sons.Google Scholar
Boylu, F. Çinku, K. Çetinel, T. Erkan, Demirer, N., KuŞçu, M. Cengiz, O. Öener, E., 2007 The separation effeciency of ReŞadiye Na-Bentonite by hyrdrocyclone XIII. National Clay Symposium Turkey Isparta 1214.Google Scholar
Brown, G., 1972 Montmorillonites X-ray Identification and Crystal Structures of Clay Minerals London Mineralogical Society 143206.Google Scholar
Brown, G. and Brindley, G.W., 1980 X-ray diffraction procedures for clay mineral identification Crystal Structures of Clay Minerals and their X-ray Identification 5 305359.CrossRefGoogle Scholar
Cebeci, Y. and Sönmez, I., 2006 Application of the Box—Wilson experimental design method for the spherical oil agglomeration of coal Fuel 85 289297.CrossRefGoogle Scholar
Christidis, G. and Scott, P.W., 1993 Laboratory evaluation of bentonites Industrial Minerals 311 5157.Google Scholar
Christidis, G.E. Scott, P.W. and Dunham, A.C., 1997 Acid activation and bleaching capacity of bentonites from the islands of Milos and Chios Aegean, Greece Applied Clay Science 12 329374.CrossRefGoogle Scholar
Christidis, G., 1998 Physical and chemical properties of some bentonite deposits of Kimolos Island, Greece Applied Clay Science 13 7998.CrossRefGoogle Scholar
Chu, L.Y. and Luo, Q., 1994 Hydrocyclone with high sharpness of separation Filtration and Separation 31 733736.CrossRefGoogle Scholar
Chung, F., 1974 Quantitative interpretation of X-ray diffraction patterns of mixtures. I. Matrix flushing method for quantitative multicomponent analysis Journal of Applied Crystallography 7 519525.CrossRefGoogle Scholar
Correia, S.L. Curto, K.A.S. Hotza, D. and Segadaes, A.M., 2004 Using statistical techniques to model the flexural strength of dried triaxial ceramic bodies Journal of the European Ceramic Society 24 28132818.CrossRefGoogle Scholar
Ferreira, SLC D Santos, W.N.L. Quintella, C.M. Neto, B.B. and Boque-Sendra, J.M., 2004 Doehlert matrix: a chemometric toll for analytical chemistry — review Talanta 63 10611067.CrossRefGoogle Scholar
Ge, Z. Li, D. and Pinnavaia, T.J., 1994 Preparation of alumina-pillared montmorillonite with high thermal stability, regular microporosity and Lewis/Bronsted acidity Microporous Materials 3 165175.CrossRefGoogle Scholar
Grim, R.E., 1962 Applied Clay Mineralogy New York International Series in Earth Sciences. McGraw-Hill Book Company.CrossRefGoogle Scholar
Grim, R.E., 1968 Clay Mineralogy New York McGraw-Hill Book Company.Google Scholar
Grim, R.E. and Giiven, N. (1978) Bentonites: Geology, Mineralogy, Properties and Uses. Developments in Sedimentology 24. Elsevier Publishing Company, New York, 256 pp.Google Scholar
Gunaraj, V. and Murugan, N., 1999 Application of response surface methodologies for predicting weld base quality in submerged arc welding of pipes Journal of Materials Processing Technology 88 266275.CrossRefGoogle Scholar
Gündoğdu, M.N., 1982 Geological, mineralogical and geochemical investigation of the Bigadic Neogene volcanosedimentary basin Turkey Hacettepe University, Ankara.Google Scholar
Güven, N. and Pollastro, R.M. (1992) Clay—Water Interface and Its Rheological Implications, CMS Workshop Lectures, vol. 4. The Clay Mineral Society, Aurora, CO, USA.Google Scholar
Habibian, M. Pazouki, M. Ghanaie, H. and Abbaspour-Sani, K., 2008 Application of hydrocyclone for removal of yeasts from alcohol fermentations broth Chemical Engineering Journal 138 1-3 3034.CrossRefGoogle Scholar
Hassan, M.S. and Abdel-Khalek, N.A., 1998 Beneficiation and applications of an Egyptian bentonite Applied Clay Science 13 99115.CrossRefGoogle Scholar
Johns, W.D. Grim, R.E. and Bradley, W.F., 1954 Quantitative estimations of clay minerals by diffraction methods Journal of Sedimentary Petrology 24 242251.Google Scholar
Kahraman, S. Önal, M. Sarιkaya, Y. and Bozdoğan, I., 2005 Characterization of silica polymorphs in kaolins by X-ray diffraction before and after phosphoric acid digestion and thermal treatment Analytica Chimica Acta 552 201206.CrossRefGoogle Scholar
Kincl, M. Turk, S. and Vrecer, F., 2005 Application of experimental design methodology in development and optimization of drug release method International Journal of Pharmaceutics 291 3949.CrossRefGoogle ScholarPubMed
Komadel, P. Bujdák, J. Madejová, J. Šucha, V. and Elsass, F., 1996 Effect of non-swelling layers on the dissolution of reduced-charge montmorillonite in hydrochloric acid Clay Minerals 31 333345.CrossRefGoogle Scholar
Komadel, P., 2003 Chemically modified smectites Clay Minerals 38 127138.CrossRefGoogle Scholar
Komine, H. and Ogata, N., 1994 Experimental study on swelling characteristics of compacted bentonite Canadian Geotechnical Journal 31 478490.CrossRefGoogle Scholar
Komine, H. and Ogata, S., 1996 Prediction for swelling characteristics of bentonite Canadian Geotechnical Journal 33 1121.CrossRefGoogle Scholar
Komine, H. and Ogata, S., 1999 Experimental study on swelling characteristics of sand-bentonite mixture for nuclear waste disposal Soils and Foundations 39 8397.CrossRefGoogle Scholar
Kwak, J.S., 2005 Application of Taguchi and response surface methodologies for geometric error in surface grinding process International Journal of Machine Tools and Manufacture 45 327334.CrossRefGoogle Scholar
Lagaly, G., 1984 Clay—organic interactions Philosophical Transactions of the Royal Society of London A311 315332.Google Scholar
Low, P.F., 1979 Nature and properties of water in montmorillonite—water systems Soil Science Society of America Journal 43 651658.CrossRefGoogle Scholar
Luckham, P.F. and Rossi, S., 1999 The colloidal and rheological properties of bentonite suspension Advances in Colloid and Interface Science 82 4392.CrossRefGoogle Scholar
Malfoy, C. Pantet, A. Monnet, P. and Righi, D., 2003 Effect of the nature of exchangeable cation and clay concentration on the rheological properties of smectite suspensions Clays and Clay Minerals 51 656663.CrossRefGoogle Scholar
Martinez, A.L. Uribe, A.S. Carrillo, F.R.P. Coreno, J.A. and Ortiz, J.C., 2003 Study of celestite flotation efficiency using sodium dodecyl sulfonate collector: factorial experiment and statistical analysis of data International Journal of Mineral Processing 70 8397.CrossRefGoogle Scholar
Massart, D.L. Vandeginste, B.G.M. Buydens, L.M.C. Jong, S. Lewi, P.J. and Smeyers Verbeke, J., 1997 Handbook of Chemometrics and Qualimetrics Part A Amsterdam Elsevier Publishing Company.Google Scholar
Minitab Inc., 2007 Meet minitab 15 .Google Scholar
Montes, G. Duplay, J. Martinez, L. Geraud, Y. and Rousset-Tournier, B., 2003 Influence of interlayer cations on the water sorption and swelling-shrinkage of MW80 bentonite Applied Clay Science 23 309321.CrossRefGoogle Scholar
Montgomery, D.C., 2001 Design and Analysis of Experiments 5th edition New York John Wiley & Sons.Google Scholar
Murray, H.H., 2000 Traditional and new applications for kaolin, smectite and polygorskite: a general overview Applied Clay Science 17 207221.CrossRefGoogle Scholar
Neaman, A. Pelletier, M. and Villieras, F., 2003 The effects of exchangeable cation, compression, heating and hydration on textural properties of bulk bentonite and its corresponding purified montmorillonite Applied Clay Science 22 153168.CrossRefGoogle Scholar
Neto, B.B. Scarminio, I.S. and Bruns, R.E., 2001 Como fazer Experimentos: Pesquisa e Desenvolvimento na Ciência e na Industria São Paulo Editora da Unicamp.Google Scholar
Obeng, D.P. Morrell, S. and Napier-Munn, T.J., 2005 Application of central composite rotatable design to modeling the effect of some operating variables on the performance of the three-product cyclone International Journal of Mineral Processing 76 181192.CrossRefGoogle Scholar
Önal, M. Sarιkaya, Y. and Alemdaroğlu, T., 2002 The effect of acid activation on some physicochemical properties of a bentonite Turkish Journal of Chemistry 26 409416.Google Scholar
Önal, M., 2007 Swelling and cation exchange capacity relationship for the samples obtained from a bentonite by acid activations and heat treatments Applied Clay Science 37 7480.CrossRefGoogle Scholar
Özbayoğlu, G. and Atalay, M.U., 2000 Beneficiation of bastnaesite by a multigravity separator Journal of Alloys and Compounds 303-304 520523.CrossRefGoogle Scholar
Özgen, S. Yιldιz, A. Çalιşkan, A. and Sabah, E., 2009 Modeling and optimization of hydrocyclone processing of low grade bentonites Applied Clay Science 46 305316.CrossRefGoogle Scholar
Pinnavaia, T.J., 1983 Intercalated clay catalysis Science 220 365371.CrossRefGoogle Scholar
Push, R., 1992 Use of bentonite for isolation of radioactive waste products Clay Minerals 27 753761.Google Scholar
Ragonese, R. Macka, M. Hughes, J. and Petocz, P., 2002 The use of the Box-Behnken experimental design in the optimisation and robustness testing of a capillary electrophoresis method for the analysis of ethambutol hydrochloride in a pharmaceutical formulation Journal of Pharmaceutical and Biomedical Analysis 27 9951007.CrossRefGoogle Scholar
Rickwood, D. Onions, J. Bendixen, B. Smyth, I., Svaorovsky, L. Thew, M.T., 1992 Prospects for the use of hydrocyclones for biological separations Hydrocyclones Analysis and Applications London Kluwer Academic 109120.CrossRefGoogle Scholar
Rytwo, G. Serben, C. Nir, S. and Margulies, L., 1991 Use of methylene blue and crystal violet for determination of exchangeable cations in montmorillonite Clays and Clay Minerals 39 551555.CrossRefGoogle Scholar
Sarikaya, Y. Önal, M. Baran, B. and Alemdaroğlu, T., 2000 The effect of thermal treatment on some of the physicochemical properties of a bentonite Clays and Clay Minerals 48 557562.CrossRefGoogle Scholar
Sharmm, L.L. and Kwak, J.C.T., 1982 Influence of exchangeable cation composition on the size and shape of montmorillonite particles in dilute suspension Clays and Clay Minerals 30 4048.Google Scholar
Souzaa, A.S. dos Santos, W.N.L. and Sergio Ferreira, L.C., 2005 Application of Box—Behnken design in the optimization of an on-line pre-concentration system using knotted reactor for cadmium determination by flame atomic absorption spectrometry Spectrochimica Acta Part B 60 737742.CrossRefGoogle Scholar
Tan, Yιlmaz, L. and Zaimoğlu, S., 2004 Variation of some engineering properties of clays with heat treatment Materials Letters 58 11761179.CrossRefGoogle Scholar
Theng, B.K.G., 1974 The Chemistry of Clay Organic Reactions London Adam Hilger.Google Scholar
Wersin, P. Curti, E. and Appelo, C.A.J., 2004 Modeling bentonite—water interactions at high solid/liquid ratios: swelling and diffuse double layer effects Applied Clay Science 26 249257.CrossRefGoogle Scholar
Williams, RA A d G Colon, I.L. Lee, M.S. and Roldan Villasana, E.J., 1994 Design Targeting of Hydrocyclone Networks Minerals Engineering 7 561576.CrossRefGoogle Scholar
Xiao, Z. and Vien, A., 2004 Experimental designs for precise parameter estimation for non-linear models Minerals Engineering 17 431436.CrossRefGoogle Scholar
Varma, R.S., 2002 Clay and clay-supported reagents in organic synthesis Tetrahedron 58 12351255.CrossRefGoogle Scholar
Yιldιz, A. Kibici, Y. Çoban, F. Bağcι, M. Dumlupunar, Kocabaş, C. Arιtan, E. and Bilge, Y., 2008 The investigation of the geological properties of Mihalgazi (Eskişehir) bentonite and evaluation of bentonite as industrial raw material .Google Scholar
Yιldιz, A. and Kuİcu, M., 2007 Mineralogy, chemistry and physical properties of bentonites from Baİören, Kütahya, W-Anatolia Clay Minerals 42 403418.CrossRefGoogle Scholar
Yong, R.N., 1999 Soil suction and soil—water potential in swelling clays in engineered clay barriers Engineering Geology 54 313.CrossRefGoogle Scholar