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Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals

Year 2022, , 1280 - 1295, 01.12.2022
https://doi.org/10.35378/gujs.939443

Abstract

The mineral and chemical composition of magnetic (tailing fraction) and non – magnetic (clean coal fraction) products from the dry magnetic separation of coal samples with high ash and sulfur contents obtained from Çanakkale Çan lignite (S1) and Manisa Kula Pabuçlu lignite (S2) were investigated in this study. The feasibility of the dry magnetic separation technique for the separation of the minerals from the coal matrix was identified as the function of coal types and particle sizes. The separation technique depends on coal fragments being weakly diamagnetic, while most of the minerals present in the coal are weakly to moderately paramagnetic. Three particle sizes (coarse-, medium-, and fine-sized) of feed lignite and their magnetic and non-magnetic fractions were separated and characterized. The influence of coal type on the magnetic separation efficiency was determined by the recovery of tailing fractions obtained from S1 and S2 lignites. The particle sizes of S1 lignite were quite lower than S2 lignite. When the fine-sized lignite samples from S1 and S2 were used, the recovery of tailing fractions was the highest compared to other sizes. The mineral compositions of S2 lignite include typically mica, smectite (clay mineral), gypsum, kaolinite (clay mineral), pyrite, quartz, and plagioclase. The results showed that the Permroll High-Intensity Magnetic Separation method for high calorific value and low ash content at the medium-sized particle was more efficient for the S2 lignite sample than the S1 lignite sample.

Thanks

Acknowledgements This study is a part of a research project on the separation of magnetic fractions from coal by magnetic separation under MTA project. Authors gratefully acknowledge to General Directorate of Mineral Research and Exploration, Department of Mineral Analysis and Technology, (MTA– MAT) in Turkey provided for financial and laboratory support for this work.

References

  • [1] BP, “Coal”, BP Statistical Review of World Energy, Pureprint Group Limited, UK, 68th Edi., 42-47, (2019).
  • [2] Vejahati, F., Xu, Z., Gupta, R., “Trace elements in coal: Associations with coal and minerals and their behaviour during coal utilization – A Review”, Fuel, 89: 904-911, (2010).
  • [3] Erarslan, C., Örgün, Y., “Mineralogical and geological characteristics of coal ash from the Northwest Thrace Region, Turkey: A Case study”, Arabian Journal of Geosciences, 10: 221-237, (2017).
  • [4] Mills, S., “Prospects for coal and clean coal technologies in Turkey”, IEA Clean Coal Centre, IEA CCC/239, London, UK, 27-40, (2014).
  • [5] Seferinoğlu, M., Paul, M., Sandström, Å., Köker, A., Toprak, S., Paul, J., “Acid leaching of coal and coal-ashes”, Fuel, 82(1): 1721-1734, (2003).
  • [6] Vassilev, V. S., Vassileva, G. C., Karayiğit, I. A., Bulut, Y., Alastuey, A., Querol, X., “Phase – mineral and chemical composition of composite samples from feed coals, bottom ashes and fly ashes at the soma power station, Turkey”, International Journal of Coal Geology, 61: 35-63, (2005).
  • [7] Rousaki, K., Couch, G., “Advanced clean coal technologies and low value coals”, IEA Clean Coal Centre, IEA CCC/39, London, UK, 76-100, (2000).
  • [8] Jenkins, R. G., Walker, P, L., “Analysis of mineral matter in coal, analytical methods for coal and coal products”, Ed., Clarence Karr, Jr., Academic Press, 1(26): 265-292, (1978).
  • [9] Bhowmick, T., Nayak, B., Varma, A. K., “Chemical and mineralogical composition of Kahara Coal, East Bokaro Coalfield, Indian”, Fuel, 208: 91-100, (2017).
  • [10] Vassilev, S. V., Vassileva, C. G., “A New Approach for the combined chemical and mineral classification of the inorganic matter in coal. 1. Chemical and mineral classification systems”, Fuel, 88: 235-245, (2009).
  • [11] Dai, S., Hower, J. C., Finkelman, R. B., Graham, J. T., French, D., Warde, C. R., Eskenazy, G., Wei, Q., Zhao, L., “Organic associations of non-mineral elements in coal: A Review”, International Journal of Coal Geology, 218(1): 103347-103367, (2020).
  • [12] Chen, Y., Cao, M., Ma, C., “Review of coal-fired electrification and magnetic separation desulfurization technology”, Applied Sciences, 9: 1158-1171, (2019).
  • [13] Tao, X., Xu, N., Xie, M., Tang, L., “Progress of the technique of coal microwave desulfurization”, International Journal of Coal Science & Technology, 1: 113-128, (2014).
  • [14] Zong, X. Q., Zhen, F. L., Bo, L., “Variables and applications on dry magnetic separator”, 3rd International Conference on Advances in Energy and Environment Research (ICAEER 2018), E3S Web of Conferences, 53: 9-18, (2018).
  • [15] Çelik, M.S., Yıldırım, I., “A New physical process for desulfurization of low-rank coals”, Fuel, 79: 1665-1669, (2000).
  • [16] Çiçek, B., Bilgesu, A. Y., Şenel, M. A., Pamuk, V., “Desulphurization of coals by flash pyrolysis followed by magnetic separation”, Fuel Processing Technology, 46: 133-142, (1996).
  • [17] ASTM standard D 2492-84 “Standard test method for forms of sulfur in coal”, ASTM International, West Conshohocken, PA, 266-269, (2002).
  • [18] ASTM standard D388-15 “Standard classification of coals by rank”, ASTM International, West Conshohocken, PA., 1-8, (2015).
  • [19] Couch, R. C., “Advanced coal cleaning technology”, IEA Clean Coal Centre, IEACR/44, UK, 1-95, (1991).
  • [20] Ibrahim, S. S., Farahat, M. M., Boulos, T. R., “Optimizing the performance of the RER magnetic separator for upgrading silica sands”, An International Journal Particulate Science and Technology, 35(1): 21-28, (2017).
  • [21] Davidson, R. M., Clarke, L. B., “Trace elements in coal”, IEA Coal Research, IEAPER/21, 1-60, (1996).
  • [22] Vassilev, S. V., Menendez, R., Borrego, A. G., Somoano M. D., and Tarazona M. R. M., “Phase-mineral and chemical composition of coal fly ashes as a basis for their multicomponent utilization. 3. Characterization of magnetic and char concentrates”, Fuel, 83: 1563-1583, (2004).
  • [23] Tuncalı, E., Çiftci, B., Toprak, S., “Chemical and technological properties of Turkish tertiary coals”, Ed., General Directorate of Mineral Research and Exploration, ISBN, 6595-47-7, Ankara, 75-187, (2002).
  • [24] Wenbin, L., Baohong G., Zhongbiao, W., “Dehydration behaviour of FGD gypsium by simultaneous TG and DSC analysis”, Journal of Thermal Analysis and Calorimetry, 104: 661-669, (2011).
  • [25] Kostakis, G., “Mineralogical composition of boiler of boiler fouling and slagging depositions and their relation to fly ash: the case of Kardia Power Plant”, Journal of Hazardous Materials, 185: 1012-1018, (2011).
  • [26] Ward, C.R., “Analysis, origin and significance of mineral matter in coal: an updated review”, International Journal of Coal Geology, 165: 1-27, (2016).
  • [27] Payá, J., Monzó, J., Borrachero, M.V., Peris-Mora, E., “Mechanical treatment of fly ashes. Part I: Physico-chemical characterization of ground fly ashes”, Cement and Concrete Research, 25(7): 1469-1479, (1995).
  • [28] Raubault, M., Fabries, J., Weisbrod, A., “Detérmination des minéraux des roches”, Ed., Lamarre- Poinat, Paris, 1: 1-365, (1963).
  • [29] Bibbly, D., “Combustion and variation of pulverized fuel ash obtained from the combustion of sub-bituminous coals, New Zealand”, Fuel, 56: 427-431, (1977).
  • [30] Vassilev, S. V., Menendez, R., Alvarez, D., Somoano, M. D., Tarazona, M. R. M., “Phase-mineral and chemical composition of coal fly ashes as a basis for their multicomponent utilization. 1. Characterization of feed coals and fly ashes”, Fuel, 82: 1793-1811, (2003).
  • [31] Hower, J. C., Rathbone, R. F., Robertson, J. D., Peterson, G., Trimble A. S., “Petrology, mineralogy, and chemistry of magnetically-separated sized fly ash”, Fuel, 78: 197-203, (1999).
  • [32] Koca, H., Koca, S., Kockar O. M., “Upgrading of Kutahya region lignites by mild pyrolysis and high intensity dry magnetic separation”, Minerals Engineering, 13: 657-661, (2000).
  • [33] Uslu, T., Atalay Ü., “Microwave heating of coal for enhanced magnetic removal of pyrite”, Fuel Processing Technology, 85: 21-29, (2003).
Year 2022, , 1280 - 1295, 01.12.2022
https://doi.org/10.35378/gujs.939443

Abstract

References

  • [1] BP, “Coal”, BP Statistical Review of World Energy, Pureprint Group Limited, UK, 68th Edi., 42-47, (2019).
  • [2] Vejahati, F., Xu, Z., Gupta, R., “Trace elements in coal: Associations with coal and minerals and their behaviour during coal utilization – A Review”, Fuel, 89: 904-911, (2010).
  • [3] Erarslan, C., Örgün, Y., “Mineralogical and geological characteristics of coal ash from the Northwest Thrace Region, Turkey: A Case study”, Arabian Journal of Geosciences, 10: 221-237, (2017).
  • [4] Mills, S., “Prospects for coal and clean coal technologies in Turkey”, IEA Clean Coal Centre, IEA CCC/239, London, UK, 27-40, (2014).
  • [5] Seferinoğlu, M., Paul, M., Sandström, Å., Köker, A., Toprak, S., Paul, J., “Acid leaching of coal and coal-ashes”, Fuel, 82(1): 1721-1734, (2003).
  • [6] Vassilev, V. S., Vassileva, G. C., Karayiğit, I. A., Bulut, Y., Alastuey, A., Querol, X., “Phase – mineral and chemical composition of composite samples from feed coals, bottom ashes and fly ashes at the soma power station, Turkey”, International Journal of Coal Geology, 61: 35-63, (2005).
  • [7] Rousaki, K., Couch, G., “Advanced clean coal technologies and low value coals”, IEA Clean Coal Centre, IEA CCC/39, London, UK, 76-100, (2000).
  • [8] Jenkins, R. G., Walker, P, L., “Analysis of mineral matter in coal, analytical methods for coal and coal products”, Ed., Clarence Karr, Jr., Academic Press, 1(26): 265-292, (1978).
  • [9] Bhowmick, T., Nayak, B., Varma, A. K., “Chemical and mineralogical composition of Kahara Coal, East Bokaro Coalfield, Indian”, Fuel, 208: 91-100, (2017).
  • [10] Vassilev, S. V., Vassileva, C. G., “A New Approach for the combined chemical and mineral classification of the inorganic matter in coal. 1. Chemical and mineral classification systems”, Fuel, 88: 235-245, (2009).
  • [11] Dai, S., Hower, J. C., Finkelman, R. B., Graham, J. T., French, D., Warde, C. R., Eskenazy, G., Wei, Q., Zhao, L., “Organic associations of non-mineral elements in coal: A Review”, International Journal of Coal Geology, 218(1): 103347-103367, (2020).
  • [12] Chen, Y., Cao, M., Ma, C., “Review of coal-fired electrification and magnetic separation desulfurization technology”, Applied Sciences, 9: 1158-1171, (2019).
  • [13] Tao, X., Xu, N., Xie, M., Tang, L., “Progress of the technique of coal microwave desulfurization”, International Journal of Coal Science & Technology, 1: 113-128, (2014).
  • [14] Zong, X. Q., Zhen, F. L., Bo, L., “Variables and applications on dry magnetic separator”, 3rd International Conference on Advances in Energy and Environment Research (ICAEER 2018), E3S Web of Conferences, 53: 9-18, (2018).
  • [15] Çelik, M.S., Yıldırım, I., “A New physical process for desulfurization of low-rank coals”, Fuel, 79: 1665-1669, (2000).
  • [16] Çiçek, B., Bilgesu, A. Y., Şenel, M. A., Pamuk, V., “Desulphurization of coals by flash pyrolysis followed by magnetic separation”, Fuel Processing Technology, 46: 133-142, (1996).
  • [17] ASTM standard D 2492-84 “Standard test method for forms of sulfur in coal”, ASTM International, West Conshohocken, PA, 266-269, (2002).
  • [18] ASTM standard D388-15 “Standard classification of coals by rank”, ASTM International, West Conshohocken, PA., 1-8, (2015).
  • [19] Couch, R. C., “Advanced coal cleaning technology”, IEA Clean Coal Centre, IEACR/44, UK, 1-95, (1991).
  • [20] Ibrahim, S. S., Farahat, M. M., Boulos, T. R., “Optimizing the performance of the RER magnetic separator for upgrading silica sands”, An International Journal Particulate Science and Technology, 35(1): 21-28, (2017).
  • [21] Davidson, R. M., Clarke, L. B., “Trace elements in coal”, IEA Coal Research, IEAPER/21, 1-60, (1996).
  • [22] Vassilev, S. V., Menendez, R., Borrego, A. G., Somoano M. D., and Tarazona M. R. M., “Phase-mineral and chemical composition of coal fly ashes as a basis for their multicomponent utilization. 3. Characterization of magnetic and char concentrates”, Fuel, 83: 1563-1583, (2004).
  • [23] Tuncalı, E., Çiftci, B., Toprak, S., “Chemical and technological properties of Turkish tertiary coals”, Ed., General Directorate of Mineral Research and Exploration, ISBN, 6595-47-7, Ankara, 75-187, (2002).
  • [24] Wenbin, L., Baohong G., Zhongbiao, W., “Dehydration behaviour of FGD gypsium by simultaneous TG and DSC analysis”, Journal of Thermal Analysis and Calorimetry, 104: 661-669, (2011).
  • [25] Kostakis, G., “Mineralogical composition of boiler of boiler fouling and slagging depositions and their relation to fly ash: the case of Kardia Power Plant”, Journal of Hazardous Materials, 185: 1012-1018, (2011).
  • [26] Ward, C.R., “Analysis, origin and significance of mineral matter in coal: an updated review”, International Journal of Coal Geology, 165: 1-27, (2016).
  • [27] Payá, J., Monzó, J., Borrachero, M.V., Peris-Mora, E., “Mechanical treatment of fly ashes. Part I: Physico-chemical characterization of ground fly ashes”, Cement and Concrete Research, 25(7): 1469-1479, (1995).
  • [28] Raubault, M., Fabries, J., Weisbrod, A., “Detérmination des minéraux des roches”, Ed., Lamarre- Poinat, Paris, 1: 1-365, (1963).
  • [29] Bibbly, D., “Combustion and variation of pulverized fuel ash obtained from the combustion of sub-bituminous coals, New Zealand”, Fuel, 56: 427-431, (1977).
  • [30] Vassilev, S. V., Menendez, R., Alvarez, D., Somoano, M. D., Tarazona, M. R. M., “Phase-mineral and chemical composition of coal fly ashes as a basis for their multicomponent utilization. 1. Characterization of feed coals and fly ashes”, Fuel, 82: 1793-1811, (2003).
  • [31] Hower, J. C., Rathbone, R. F., Robertson, J. D., Peterson, G., Trimble A. S., “Petrology, mineralogy, and chemistry of magnetically-separated sized fly ash”, Fuel, 78: 197-203, (1999).
  • [32] Koca, H., Koca, S., Kockar O. M., “Upgrading of Kutahya region lignites by mild pyrolysis and high intensity dry magnetic separation”, Minerals Engineering, 13: 657-661, (2000).
  • [33] Uslu, T., Atalay Ü., “Microwave heating of coal for enhanced magnetic removal of pyrite”, Fuel Processing Technology, 85: 21-29, (2003).
There are 33 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Chemical Engineering
Authors

Meryem Seferinoglu 0000-0002-3260-6598

Derya Düzenli 0000-0002-0057-8692

Publication Date December 1, 2022
Published in Issue Year 2022

Cite

APA Seferinoglu, M., & Düzenli, D. (2022). Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals. Gazi University Journal of Science, 35(4), 1280-1295. https://doi.org/10.35378/gujs.939443
AMA Seferinoglu M, Düzenli D. Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals. Gazi University Journal of Science. December 2022;35(4):1280-1295. doi:10.35378/gujs.939443
Chicago Seferinoglu, Meryem, and Derya Düzenli. “Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals”. Gazi University Journal of Science 35, no. 4 (December 2022): 1280-95. https://doi.org/10.35378/gujs.939443.
EndNote Seferinoglu M, Düzenli D (December 1, 2022) Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals. Gazi University Journal of Science 35 4 1280–1295.
IEEE M. Seferinoglu and D. Düzenli, “Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals”, Gazi University Journal of Science, vol. 35, no. 4, pp. 1280–1295, 2022, doi: 10.35378/gujs.939443.
ISNAD Seferinoglu, Meryem - Düzenli, Derya. “Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals”. Gazi University Journal of Science 35/4 (December 2022), 1280-1295. https://doi.org/10.35378/gujs.939443.
JAMA Seferinoglu M, Düzenli D. Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals. Gazi University Journal of Science. 2022;35:1280–1295.
MLA Seferinoglu, Meryem and Derya Düzenli. “Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals”. Gazi University Journal of Science, vol. 35, no. 4, 2022, pp. 1280-95, doi:10.35378/gujs.939443.
Vancouver Seferinoglu M, Düzenli D. Mineral and Chemical Characterization of Magnetic and Non - Magnetic Products Obtained from Dry Magnetic Enrichment of Lignite Coals. Gazi University Journal of Science. 2022;35(4):1280-95.