Enrichment of Algerian kaolin using froth flotation method

The objective of this research is to study the removal of coloring impurities from Algerian kaolin ore (Tamazert kaolin, TK) located in the eastern region of Algeria, utilizing froth flotation process. The results obtained from XRF, SEM, and XRD characterization demonstrate that this local material is an alumino-silicate containing kaolinite, along with impurities such as Fe2O3 (> 2.7 % by weight) and TiO2 (0.28 % by weight) which contribute to its coloring. After homogenization, crushing and milling, several froth flotation tests were conducted on TK. The results revealed that Tamazert kaolin exhibits favorable performance with froth flotation, in order to improve its properties. Based on the results obtained, it can be concluded that all fractions can be treated effectively using froth flotation with an optimal mass yield (weight recovery) of 79.84 % in concentrate for the fraction of 20–40 μm. Iron and titanium, the main coloring impurities in Tamazert kaolin, were reduced from 2.7 % to 0.08 % by weight for Fe2O3 in the fraction 20-40 μm, and from 0.28 % to 0.04 % by weight for TiO2 in the same fraction, as determined by the optimum test. The significant reduction in coloring impurities (Fe2O3 and TiO2) achieved through the flotation process confirms that iron is present in a free state in Tamazert kaolin. It can be ultimately confirmed that the froth flotation process can be a potentially effective process to improve the quality of Tamazert kaolin ore by removing Fe2O3 and TiO2 with satisfactory results which meet the requirements of local companies.

1. Bundy W. M. The diverse industrial applications of kaolin. In: Murray H. H., Bundy W., Harvey C. (Eds.) Kaolin, Genesis and Utilization. Special Publication 1. Boulder, Colorado: The Clay Mineral Society; 1993. Pp. 43–73.

2. Murray H. H., Keller W. Kaolins, kaolins, and kaolins. In: Murray H. H., Bundy W., Harvey C. (Eds.) Kaolin, Genesis and Utilization. Special Publication 1. Boulder, Colorado: The Clay Mineral Society; 1993. Pp. 1–24.

3. Muller J. P., Calas G. Genetic significance of paramagnetic centers in kaolinites. In: In: Murray H. H., Bundy W., Harvey C. (Eds.) Kaolin, Genesis and Utilization. Special Publication 1. Boulder, Colorado: The Clay Mineral Society; 1993. Pp. 261–290.

4. Clozel B., Allard T., Muller J. P. Nature and stability of radiation-induced defects in natural kaolinites: new results and a reappraisal of published works. Clays and Clay Minerals. 1994;42:657–666. https://doi.org/10.1346/CCMN.1994.0420601

5. Grimshaw R. W. The chemistry and physics of clays and other ceramic materials. 4th ed. London: Ernest Benn; 1971.

6. Grim R. E. Clay mineralogy. 2nd ed. New York: McGraw-Hill Book Company, International Series in the Earth and Planetary Sciences; 1968. P. 596.

7. Wills B. A., Finch J. Wills’ mineral processing technology. An introduction to the practical aspects of ore treatment and mineral recovery. 8th ed. Butterworth-Heinemann; 2015. Pp. 266–268.

8. Rousseau R. W. Handbook of separation process technology. NY, USA: John Wiley & Sons, Inc.; 1987. 775 p.

9. Tao D. Role of bubble size in flotation of coarse and fine particles – A review. Separation, Science and Technology. 2005;39(4):741–760. https://doi.org/10.1081/SS-120028444

10. Blazy P. La valorisation des minerais. Presses Universitaires de France; 1970. 415 p. (In French)

11. Zhengchang Sh. Principles and Technologies of Flotation Machines. Beijing General Research Institute of Mining and Metallurgy (BGRIMM), Beijing, China; 2021. https://doi.org/10.1007/978-981-16-0332-7

12. Young R. H., Morris H. H. Method of treating clay to improve its whiteness. U.S Patent. 1985. No. 4,492,628.

13. Öster R., Schreck B., Rybinski W., Dobiás B. New reagent systems for the flotation of kaolinite. Minerals Engineering. 1992;5(3–5):445–456.

14. Yoon R. H., Nagaraj D. R., Wang S. S., Hildebrand T. M. Benefication of kaolin clay by froth flotation using hydroxamate collectors. Minerals Engineering. 1992;5(3–5):457–467.

15. Murray H. H. Major Kaolin Processing Developments. International Journal of Mineral Processing. 1980;7:263–274.

16. Fuerstenau M. C., Miller J. D., Kuhn M. C. Chemistry of flotation. New York: American Institute of Mining, Metallurgical and Petroleum Engineers, Inc.; 1985. P. 132.

17. Köster R., Schreck B., von Rybinski W., Dobias B. New reagent systems for the flotation of kaolinite. Minerals Engineering. 1992;5(3–5):445–56. https://doi.org/10.1016/0892-6875(92)90224-W

18. Jiang H., Sun Z., Xu L., Hu Y., Huang K., Zhu S. A comparison study of the flotation and adsorption behaviors of diaspore and kaolinite with quaternary ammonium collectors. Minerals Engineering. 2014;65:124–129. https://doi.org/10.1016/j.mineng.2014.05.023

19. Castelein O. Influence de la vitesse de traitement thermique sur le comportement du kaolin bio: application au frittage rapide. Thèse de doctorat de l’université de Limoges. 2000. (In French)

20. Amigo J. M., Bastida M., Sanz J. et al. Crystallinity of Lower Cretaceous kaolinites of Teruel (Spain). Applied Clay Science. 1994;9:51–69. https://doi.org/10.1016/0169-1317(94)90014-0

21. Pilov P. I., Petrova O. V. Procédés et machines de traitement des minéraux utiles. Le manuel. Université Nationale des Mines; 2013.

22. Trahar W. J., Warren L. J. The floatability of very fine particles – A review. International Journal of Mineral Processing. 1976;3:103–131. https://doi.org/10.1016/0301-7516(76)90029-6