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Infrared Spectroscopy as the Method for Evaluating Technological Properties of Minerals and Their Behavior in Technological Processes

Холошин, Ігор Віталійович; Пантелєєва, Наталя Борисівна; Трунін, Олександр Миколайович; Бурман, Людмила Володимирівна; Калініченко, Ольга Олександрівна

URI: http://elibrary.kdpu.edu.ua/xmlui/handle/123456789/3929
https://doi.org/10.31812/123456789/3929

Date: 2020

Abstract:

Infrared spectroscopy (IR) is a highly effective method for the analysis of minerals, rocks and ores, capable of solving a whole range of problems when choosing innovative solutions for the technological processing of various types of mineral raw materials. The article considers the main directions of using the infrared spectroscopy method in assessing the technological properties of minerals and their behavior in technological processes: evaluation of the grade (quality) of mineral raw materials; analysis of the behavior of minerals in the technological process with prediction of their technological properties; analysis of changes in the structure and properties of minerals in technological processes; operational analysis of mineral substances at various stages of technological processing. The article illustrates all aspects of the use of infrared spectroscopy at various stages of studying the material composition of mineral raw materials in its enrichment assessment by specific examples of solving problems arising from the technological redistribution of various types of ore and non-metallic minerals.

Description:

1. B. Pirogov, GMV. 1, 5–17 (2008) 2. V. Farmer JMM. 31, 241–329 (1958) 3. M. Mecik, T. Shishelova, V. Liopo, JAS. 3, 464– 465 (1966) 4. T. Shishelova, A. Kolodeznikova, V. Shulga, FI. 2 (15), 3294–3298 (2015) 5. E. Giesekke, JMP 11, 9–56 (1983) 6. B. Pirogov, G. Porotov, I. Holoshin, V. Tarasenko, Tehnologicheskaya mineralogiya zheleznyh rud (Тechnological Mineralogy of Iron Ores). (Nauka, Leningrad, 1982) 7. B. Pirogov, A. Trunin, I. Holoshin, GMV. 1, 78–87 (2001) 8. A. Moiseenko, L. Orlov, G. Bogatkin, V. Strelchenko, V. Komandrovskij, I. Egorova, MNTO PRIB. 11 (41), 21–27 (2003) 9. B. Pirogov, I. Holoshin, A. Trunin, A.s. 17879 SSSR, G01V9/00/(SSSR). No. 1783461, 23.12.1992 10. Yu. Batura, M. Uglovskaya, OBRUD 5, 24–25 (2005) 11. J. Miller, J. Kellar, W. Cross, in Adv Coal Miner Process Using Flotation Proc Eng Found Conf., (Littleton, 1998), pp. 33–44 12. V. Revnivcev, G. Dolivo-Dobrovolskaya, P. Vladimirov, Tehnologicheskaya mineralogiya oblomochnyh malyh chastic (Technological mineralogy of clastic small particles). (Nauka, SPb, 1993) 13. M. Hohulya, M. Maslova, L. Gerasimova, GIAB 2, 180–192 (2013) 14. A. Remizov, D. Kamalova, R. Skochilov, I. Suvorova, N. Batyrshin, Kh.E. Kharlampidi, VKY 700, 73-79, (2004) 15. I. Plyusnina, Infrakrasnye spektry mineralov (Infrared Spectra of Minerals). (Nauka, Mоscow, 1977) 16. V. Chanturiya, V. Makarov, A. Kalinkin et al, CM 10, 80–85 (2000) 17. V. Komandrovskij, A. Moiseenko, ATSNP. 8, 25– 28 (2012) 18. R. Skochilov, A. Fshman, A. Ivanov, VKY 5, 135– 142 (2011) 19. R. Clark, T. Roush, Reflectance spectroscopy: quantitative analysis techniques for remote sensing applications. JGR (1984). doi:10.1029/JB089iB07p06329 20. A. Smith, Pricladnaya IK spektroskopiya (Applied IR Spectroscopy). (Mir, Mоscow, 1982), p. 328 21. V. Chanturiya, Yu. Brylyakov, E. Kopoprulina, M. Ryazanceva, FHPRPI (SO RAN) 4, 136–149 (2014) 22. V. Chanturiya, I. Bunin, M. Ryazanceva, I. Habarova, E. Koporulina, N. Anashkina, Aktivaciya poverhnosti i napravlennoe izmenenie fizikohimicheskih i tehnologicheskih svojstv galenita pri vozdejstvii nanosekundnyh elektromagnitnyh impulsov (Surface activation and directional change in the physicochemical and technological properties of galena when exposed to nanosecond electromagnetic pulses). FHPRPI 3, 154–169 (2014) 23. E. Ozhogina, A. Rogozhin, Prognoznaya ocenka tehnologicheskih svojstv poleznyh iskopaemyh metodami prikladnoj mineralogii (Predictive evaluation of technological properties of mineral resources by applied mineralogy methods), in Seminar on Technological Mineralogy Moscow, ed. by V. Shchiptsov, April 9–11, 2012 (Petrozavodsk, 2013), pp. 46–49 24. A. Guatame-García, M. Buxton, F. Deon, C. Lievens, C. Hecker, MEMR 11(2), 420–421 (2018) 25. I. Plaksin, V. Solnyshkin, Infrakrasnaya spektroskopiya poverhnostnyh sloev reagentov na mineralah (Infrared spectroscopy of surface layers of reagents on minerals). (Nauka, Moscow, 1966) 26. R.L. Frost, Hydroxyl deformation in kaolins. Clays and Clay Minerals 46(3), 280–289 (1998). doi:10.1346/ccmn.1998.0460307 27. R.L. Frost, É. Makó, J. Kristóf, J.T. Kloprogge, Modification of kaolinite surfaces through mechanochemical treatment – a mid-IR and near-IR spectroscopic study, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy 58(13), 2849–2859 (2002). doi:10.1016/S1386- 1425(02)00033-1 28. R.L. Frost, A.M. Vassallo, The dehydroxylation of the kaolinite clay minerals using infrared emission spectroscopy. Clays and Clay Minerals 44(5), 635– 651 (1996). doi:10.1346/CCMN.1996.0440506 29. R. Lima, P. Brandao, A. Peres, Min. Engin. 18, 267– 273 (2005) 30. E. Malinowski, Factor analysis in chemistry (Wiley, Hoboken, 2002), p. 432 31. Xiu Liancun, Zheng Zhizhong, Chen Chunxia, Gao Yang, in International Conference on Progress in Informatics and Computing 2017

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