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Year 2021, Volume: 25 Issue: 3, 821 - 833, 30.06.2021
https://doi.org/10.16984/saufenbilder.733658

Abstract

References

  • [1] R.P. Bhagat, U. Chattoray, and S.K. Sil, “Porosity of sinter and its relation with the sintering indices”, ISIJ International, vol. 46, no. 11, p. 1728-1730, 2006.
  • [2] T. Umadevi, R. Sah, and P. C. Mahapatra, “Influence of sinter basicity (CaO/SiO2) on low and high alumina iron ore sinter quality”, Mineral Processing and Extractive Metallurgy, 123(2), 75-85, 2014.
  • [3] R. Chaigneau, “Fluxed sinter formation and SFCA reduction under Simulated Conditions”, PhD Thesis, Delft University Press, p. 12-28, 1994.
  • [4] L.H. Hsieh and J.A. Whiteman, “Effect of oxygen potential on mineral formation in lime-fluxed iron ore sinter”, ISIJ International, vol. 29, no. 8, p. 625- 634, 1989.
  • [5] C. E. Loo, R. P. Williams, and L. T. Matthews, “Influence of material properties on high temperature zone reactions in sintering of iron ore”, Transactıons of The Institution of Mining And Metallurgy Sectıon C-Mineral Processing and Extractive Metallurgy, vol.101, p. 7-15, 1992.
  • [6] N. Chakraborti, K. Deb, and A. Jha, “A genetic algorithm based heat transfer analysis of a bloom re-heating furnace”, Steel Research, vol. 71, no. 10, p. 396-402, 2000.
  • [7] N. A. Webster, M. I. Pownceby, I. C. Madsen, and J. A. Kimpton, “Silico-ferrite of calcium and aluminum (SFCA) iron ore sinter bonding phases: new insights into their formation during heating and cooling”, Metallurgical and Materials Transactions B, 43(6), 1344-1357, 2012.
  • [8] N.J. Bristow and A.G. Waters, “Role of SFCA in promoting high-temperature reduction properties of iron ore sinters”. Mineral Processing & Extractive Metallurgy, Section C. vol. 100. p. 1-4, 1991.
  • [9] S. Nicol, J. Chen, M. I. Pownceby, and N. A. Webster, “A Review of the Chemistry, Structure and Formation Conditions of Silico-Ferrite of Calcium and Aluminum (SFCA) Phases”, ISIJ International, 58(12), 2157-2172, 2018.
  • [10] T. Takayama, R. Murao, and M. Kimura, “Quantitative Analysis of Mineral Phases in Iron-ore Sinter by the Rietveld Method of X-ray Diffraction Patterns”, ISIJ International, ISIJINT-2017, 2018.
  • [11] M. Kama, T. Miyazaki, K. Ito, Y. Hida, and M. Sasaki, “Morphological analysis of calcium ferrite and hematite in sintered ore”, Transactions ISIJ. vol. 24, 1984.
  • [12] W.G. Mumme, “The crystal structure of SFCA-II, Ca5.1Al9.3Fe3+ 14.30Fe2+ 0.55O48, a homologue of the aenigmatite structure type, and new structure type, and new crystal refinement of SFCA, Ca2Al5Fe7O20”, Implications for the nature of the ternary-phase solid-solution previously reported in the CaO-Al2O3-iron oxide system, Neues Jahrbuch Miner. Abh., vol. 178, no. 3, p.307-335, 2003.
  • [13] M. I. Pownceby, N. A. S. Webster, J. R. Manuel, and N. Ware, “The influence of ore composition on sinter phase mineralogy and strength”, Mineral Processing and Extractive Metallurgy, 125(3), 140-148, 2016.
  • [14] W.G. Mumme, J.M.F. Clout, and R.W. Gable, “The crystal structure of SFCA-I Ca3.18Fe3+ 14.66Al1.34Fe2+ 0.82O28, a homologue of the aenigmatite structure type, and new structure type, and new crystal refinements of β-CCF, Ca2.99Fe3+ 14.30Fe2+ 0.55O25 and Mg-free SFCA, Ca2.45Fe3+ 9.04Al1.74Fe2+ 0.16Si0.6O20”. Neues Jahrbuch Miner. Abh, vol. 173, no. 1, p. 93-117, 1988.
  • [15] M. I. Pownceby and J.M.F. Clout, “Importance of fine iron ore chemical composition and high temperature phase relations, applications to iron ore sintering and pelletizing”, Mineral Processing and Extractive Metallurgy, vol. 112, p. 44-51, 2003.
  • [16] W. Wang, X. H. Chen, R. S. Xu, J. Li, W. J. Shen, and S. P. Wang, “Research progress on multiscale structural characteristics and characterization methods of iron ore sinter”, Journal of Iron and Steel Research International, 1-13, 2020.
  • [17] R. Mežibrický, M. Fröhlichová, R. Findorák, and V. S. Goettgens, “Ore Assimilation and Secondary Phases by Sintering of Rich and High-Gangue Iron Ores”, Minerals, 9(2), 128, 2019.
  • [18] T. Harvey, “Influence of Mineralogy and Pore Structure on the Reducibility and Strength of Iron Ore Sinter”, Doctoral dissertation, University of Pretoria, Republic of South Africa, 2020.
  • [19] M. A. Nyembwe, “Study of sinter reactions when fine iron ore is replaced with coarse ore, using an infrared furnace and sinter pot tests”, Doctoral dissertation, The University of Newcastle, Australia, 2012.
  • [20] D. Fernández-González, I. Ruiz-Bustinza, J. Mochón, C. González-Gasca, and L. F. Verdeja, “Iron ore sintering: Process”. Mineral Processing and Extractive Metallurgy Review, 38(4), 215-227, 2017.
  • [21] A. Cores, L. F. Verdeja, S. Ferreira, I. Ruiz-Bustinza, and J. Mochon, Editor's Page: “Iron ore sintering. Part 1. Theory and practice of the sintering process”, Rev. Avances en Sistemas Informática, 10 (1), 152-171, 2013.
  • [22] S. Blake, R.G. Launsby, and D. L. Weese, “Experimental design meets the realities of the 1990s”, Quality Progress, p.99-101, 1994.
  • [23] P.R Dawson, J. Ostwald, and K.M. Hayes, “The influence of sintering temperature profile on the mineralogy and properties of iron ore sinters”, Proc. Aust. Inst. of Mining and Metallurgy, p. 163-169,1984.
  • [24] A. Cores, A. Babich, M. Muñiz, S. Ferreira, and J. Mochon, “The influence of different iron ores mixtures composition on the quality of sinter”, ISIJ International, vol. 50 , no. 8, p. 1089-1098, 2010.
  • [25] M.S. De Magalhaes and P.R.G. Brandao, “Microstructures of industrial sinters from Quadrilatero Ferrifero’s iron ores”, Minerals Engineering, Elsevier, p.1251, 2003.
  • [26] M. I. Pownceby and T.R.C. Patrick, “Stability of SFC (silico-ferrite of calcium): solid solution limits, thermal stability and selected phase relationships within the Fe2O3-CaOSiO2 (FCS) system”. European Journal of Mineralogy. vol. 12. p. 455-468, 2000.
  • [27] N. V. Y. Scarlett, M. I. Pownceby, I. C. Madsen, and A. N. Christensen, “Reaction sequences in the formation of silico-ferrites of calcium and aluminum in iron ore sinter”, Metallurgical and materials transactions B, vol. 35B, p. 929- 936, 2004.
  • [28] Y. Ishikawa, Y. Shimomura, M. Sasaki, and H. Toda, “Improvement of sinter quality based on the mineralogical properties of ores”, Ironmaking Proceedings. vol. 42. p. 17-29, 1983.
  • [29] L. X. Yang and E. Matthews, “Sintering reactions of magnetite concentrates under various atmospheres”, ISIJ International, vol. 37, no. 11, p. 1057-1065, 1997.
  • [30] S. Nicol, E. Jack, and P. C. Hayes, “Controlled Solidification of Liquids within the SFC Primary Phase Field of the Fe2O3-CaO-SiO2 System in Air”, Metallurgical and Materials Transactions B, 50(6), 3027-3038, 2019.
  • [31] N.V.Y. Scarlett, M. I. Pownceby, I. C Madsen, and A. N. Christensen, “In situ X-ray diffraction analysis of iron ore sinter”, Journal of Applied crystallography, vol. 37, no. 3, p. 362-368, 2004.
  • [32] P. Łechtańska and G. Wielgosiński, “The use of ammonium sulfate as an inhibitor of dioxin synthesis in iron ore sintering process”, Ecological Chemistry and Engineering, 2014.
  • [33] R. A. Young, “The Rietveld method, International Union Crystallography”, Oxford University Press, Oxford, 298p, 1993.

A Study on Analysis of Sinter Microstructure and Phase Morphology

Year 2021, Volume: 25 Issue: 3, 821 - 833, 30.06.2021
https://doi.org/10.16984/saufenbilder.733658

Abstract

Sinter is a blast furnace input material obtained by heating to 900-1200 oC without full melting and adhering to each other with superficial melting. It is considered as a multi-phase material with its sinter heterogeneous microstructure. In general, the main mineral phases are hematite, magnetite, silicoferrite of calcium and aluminium (SFCA) and silicates. By determining the SFCA structure in the sinter material, the sintering process will be made more stable and important parameters affecting the quality in the sintering process will be examined. Sinter material obtained from iron ore, iron and steel industry by products and auxiliary materials. The scope of this project is the determination of the amount of SFCA formed by bonding SiO2, CaO, Fe2O3, Al2O3 and MgO compounds and monitoring this value as a parameter by the enterprise. Sinter samples having different characteristic features will be made ready for X-ray diffraction (XRD) and optical microscopy inspections by polishing, etching and freezing in epoxy for mineralogical researches. Before raw data obtained from the analysis is evaluated at Autoquan, they will be converted into Autoquan format and then, they will be read in XRD device and mineralogical composition of the sinter will be revealed by XRD analyses. Detailed view of mineralogical compounds will be investigated so as to complete scanning electron microscope (SEM) analyses and XRD analyses; elemental composition of the compounds and valence conditions of the elements will be researched by energy dispersive spectroscopy (EDS) method. Hematite, magnetite, calcium ferrite phase structures in different formations will be studied subject to melting and temperature during optical microscopy studies conducted on sinter samples. Furthermore, it will be researched variations of SFCA, SFCA-I and SFCA-II phase structures within the sinter matrix subject to different raw material input and process parameters. It will be ensured to interpret the results through rietveld method.

References

  • [1] R.P. Bhagat, U. Chattoray, and S.K. Sil, “Porosity of sinter and its relation with the sintering indices”, ISIJ International, vol. 46, no. 11, p. 1728-1730, 2006.
  • [2] T. Umadevi, R. Sah, and P. C. Mahapatra, “Influence of sinter basicity (CaO/SiO2) on low and high alumina iron ore sinter quality”, Mineral Processing and Extractive Metallurgy, 123(2), 75-85, 2014.
  • [3] R. Chaigneau, “Fluxed sinter formation and SFCA reduction under Simulated Conditions”, PhD Thesis, Delft University Press, p. 12-28, 1994.
  • [4] L.H. Hsieh and J.A. Whiteman, “Effect of oxygen potential on mineral formation in lime-fluxed iron ore sinter”, ISIJ International, vol. 29, no. 8, p. 625- 634, 1989.
  • [5] C. E. Loo, R. P. Williams, and L. T. Matthews, “Influence of material properties on high temperature zone reactions in sintering of iron ore”, Transactıons of The Institution of Mining And Metallurgy Sectıon C-Mineral Processing and Extractive Metallurgy, vol.101, p. 7-15, 1992.
  • [6] N. Chakraborti, K. Deb, and A. Jha, “A genetic algorithm based heat transfer analysis of a bloom re-heating furnace”, Steel Research, vol. 71, no. 10, p. 396-402, 2000.
  • [7] N. A. Webster, M. I. Pownceby, I. C. Madsen, and J. A. Kimpton, “Silico-ferrite of calcium and aluminum (SFCA) iron ore sinter bonding phases: new insights into their formation during heating and cooling”, Metallurgical and Materials Transactions B, 43(6), 1344-1357, 2012.
  • [8] N.J. Bristow and A.G. Waters, “Role of SFCA in promoting high-temperature reduction properties of iron ore sinters”. Mineral Processing & Extractive Metallurgy, Section C. vol. 100. p. 1-4, 1991.
  • [9] S. Nicol, J. Chen, M. I. Pownceby, and N. A. Webster, “A Review of the Chemistry, Structure and Formation Conditions of Silico-Ferrite of Calcium and Aluminum (SFCA) Phases”, ISIJ International, 58(12), 2157-2172, 2018.
  • [10] T. Takayama, R. Murao, and M. Kimura, “Quantitative Analysis of Mineral Phases in Iron-ore Sinter by the Rietveld Method of X-ray Diffraction Patterns”, ISIJ International, ISIJINT-2017, 2018.
  • [11] M. Kama, T. Miyazaki, K. Ito, Y. Hida, and M. Sasaki, “Morphological analysis of calcium ferrite and hematite in sintered ore”, Transactions ISIJ. vol. 24, 1984.
  • [12] W.G. Mumme, “The crystal structure of SFCA-II, Ca5.1Al9.3Fe3+ 14.30Fe2+ 0.55O48, a homologue of the aenigmatite structure type, and new structure type, and new crystal refinement of SFCA, Ca2Al5Fe7O20”, Implications for the nature of the ternary-phase solid-solution previously reported in the CaO-Al2O3-iron oxide system, Neues Jahrbuch Miner. Abh., vol. 178, no. 3, p.307-335, 2003.
  • [13] M. I. Pownceby, N. A. S. Webster, J. R. Manuel, and N. Ware, “The influence of ore composition on sinter phase mineralogy and strength”, Mineral Processing and Extractive Metallurgy, 125(3), 140-148, 2016.
  • [14] W.G. Mumme, J.M.F. Clout, and R.W. Gable, “The crystal structure of SFCA-I Ca3.18Fe3+ 14.66Al1.34Fe2+ 0.82O28, a homologue of the aenigmatite structure type, and new structure type, and new crystal refinements of β-CCF, Ca2.99Fe3+ 14.30Fe2+ 0.55O25 and Mg-free SFCA, Ca2.45Fe3+ 9.04Al1.74Fe2+ 0.16Si0.6O20”. Neues Jahrbuch Miner. Abh, vol. 173, no. 1, p. 93-117, 1988.
  • [15] M. I. Pownceby and J.M.F. Clout, “Importance of fine iron ore chemical composition and high temperature phase relations, applications to iron ore sintering and pelletizing”, Mineral Processing and Extractive Metallurgy, vol. 112, p. 44-51, 2003.
  • [16] W. Wang, X. H. Chen, R. S. Xu, J. Li, W. J. Shen, and S. P. Wang, “Research progress on multiscale structural characteristics and characterization methods of iron ore sinter”, Journal of Iron and Steel Research International, 1-13, 2020.
  • [17] R. Mežibrický, M. Fröhlichová, R. Findorák, and V. S. Goettgens, “Ore Assimilation and Secondary Phases by Sintering of Rich and High-Gangue Iron Ores”, Minerals, 9(2), 128, 2019.
  • [18] T. Harvey, “Influence of Mineralogy and Pore Structure on the Reducibility and Strength of Iron Ore Sinter”, Doctoral dissertation, University of Pretoria, Republic of South Africa, 2020.
  • [19] M. A. Nyembwe, “Study of sinter reactions when fine iron ore is replaced with coarse ore, using an infrared furnace and sinter pot tests”, Doctoral dissertation, The University of Newcastle, Australia, 2012.
  • [20] D. Fernández-González, I. Ruiz-Bustinza, J. Mochón, C. González-Gasca, and L. F. Verdeja, “Iron ore sintering: Process”. Mineral Processing and Extractive Metallurgy Review, 38(4), 215-227, 2017.
  • [21] A. Cores, L. F. Verdeja, S. Ferreira, I. Ruiz-Bustinza, and J. Mochon, Editor's Page: “Iron ore sintering. Part 1. Theory and practice of the sintering process”, Rev. Avances en Sistemas Informática, 10 (1), 152-171, 2013.
  • [22] S. Blake, R.G. Launsby, and D. L. Weese, “Experimental design meets the realities of the 1990s”, Quality Progress, p.99-101, 1994.
  • [23] P.R Dawson, J. Ostwald, and K.M. Hayes, “The influence of sintering temperature profile on the mineralogy and properties of iron ore sinters”, Proc. Aust. Inst. of Mining and Metallurgy, p. 163-169,1984.
  • [24] A. Cores, A. Babich, M. Muñiz, S. Ferreira, and J. Mochon, “The influence of different iron ores mixtures composition on the quality of sinter”, ISIJ International, vol. 50 , no. 8, p. 1089-1098, 2010.
  • [25] M.S. De Magalhaes and P.R.G. Brandao, “Microstructures of industrial sinters from Quadrilatero Ferrifero’s iron ores”, Minerals Engineering, Elsevier, p.1251, 2003.
  • [26] M. I. Pownceby and T.R.C. Patrick, “Stability of SFC (silico-ferrite of calcium): solid solution limits, thermal stability and selected phase relationships within the Fe2O3-CaOSiO2 (FCS) system”. European Journal of Mineralogy. vol. 12. p. 455-468, 2000.
  • [27] N. V. Y. Scarlett, M. I. Pownceby, I. C. Madsen, and A. N. Christensen, “Reaction sequences in the formation of silico-ferrites of calcium and aluminum in iron ore sinter”, Metallurgical and materials transactions B, vol. 35B, p. 929- 936, 2004.
  • [28] Y. Ishikawa, Y. Shimomura, M. Sasaki, and H. Toda, “Improvement of sinter quality based on the mineralogical properties of ores”, Ironmaking Proceedings. vol. 42. p. 17-29, 1983.
  • [29] L. X. Yang and E. Matthews, “Sintering reactions of magnetite concentrates under various atmospheres”, ISIJ International, vol. 37, no. 11, p. 1057-1065, 1997.
  • [30] S. Nicol, E. Jack, and P. C. Hayes, “Controlled Solidification of Liquids within the SFC Primary Phase Field of the Fe2O3-CaO-SiO2 System in Air”, Metallurgical and Materials Transactions B, 50(6), 3027-3038, 2019.
  • [31] N.V.Y. Scarlett, M. I. Pownceby, I. C Madsen, and A. N. Christensen, “In situ X-ray diffraction analysis of iron ore sinter”, Journal of Applied crystallography, vol. 37, no. 3, p. 362-368, 2004.
  • [32] P. Łechtańska and G. Wielgosiński, “The use of ammonium sulfate as an inhibitor of dioxin synthesis in iron ore sintering process”, Ecological Chemistry and Engineering, 2014.
  • [33] R. A. Young, “The Rietveld method, International Union Crystallography”, Oxford University Press, Oxford, 298p, 1993.
There are 33 citations in total.

Details

Primary Language English
Subjects Material Production Technologies
Journal Section Research Articles
Authors

Ömer Saltuk Bölükbaşı 0000-0002-8862-009X

Publication Date June 30, 2021
Submission Date May 7, 2020
Acceptance Date May 5, 2021
Published in Issue Year 2021 Volume: 25 Issue: 3

Cite

APA Bölükbaşı, Ö. S. (2021). A Study on Analysis of Sinter Microstructure and Phase Morphology. Sakarya University Journal of Science, 25(3), 821-833. https://doi.org/10.16984/saufenbilder.733658
AMA Bölükbaşı ÖS. A Study on Analysis of Sinter Microstructure and Phase Morphology. SAUJS. June 2021;25(3):821-833. doi:10.16984/saufenbilder.733658
Chicago Bölükbaşı, Ömer Saltuk. “A Study on Analysis of Sinter Microstructure and Phase Morphology”. Sakarya University Journal of Science 25, no. 3 (June 2021): 821-33. https://doi.org/10.16984/saufenbilder.733658.
EndNote Bölükbaşı ÖS (June 1, 2021) A Study on Analysis of Sinter Microstructure and Phase Morphology. Sakarya University Journal of Science 25 3 821–833.
IEEE Ö. S. Bölükbaşı, “A Study on Analysis of Sinter Microstructure and Phase Morphology”, SAUJS, vol. 25, no. 3, pp. 821–833, 2021, doi: 10.16984/saufenbilder.733658.
ISNAD Bölükbaşı, Ömer Saltuk. “A Study on Analysis of Sinter Microstructure and Phase Morphology”. Sakarya University Journal of Science 25/3 (June 2021), 821-833. https://doi.org/10.16984/saufenbilder.733658.
JAMA Bölükbaşı ÖS. A Study on Analysis of Sinter Microstructure and Phase Morphology. SAUJS. 2021;25:821–833.
MLA Bölükbaşı, Ömer Saltuk. “A Study on Analysis of Sinter Microstructure and Phase Morphology”. Sakarya University Journal of Science, vol. 25, no. 3, 2021, pp. 821-33, doi:10.16984/saufenbilder.733658.
Vancouver Bölükbaşı ÖS. A Study on Analysis of Sinter Microstructure and Phase Morphology. SAUJS. 2021;25(3):821-33.