References
- Kuang S, Li Z, Yu A. Recent developments in the modeling and simulation of blast furnace ironmaking. Steel Res Int. 2017;87(9999):1–25.
- Ishii K. Advanced pulverised coal injection technology and blast furnace operation. Oxford: Elsevier; 2000.
- Mathieson JG, Truelove JS, Rogers H. Toward an understanding of coal combustion in blast furnace tuyere injection. Fuel. 2005;84(10):1229–1237.
- Jamaluddin AS, Wall TF, Truelove JS. Combustion of pulverised coal as a tuyere injectant to the blast furnace. Symp (Int) Combus Inst. 1986;21(1):575–584.
- Babich A, Senk D, Born S. Interaction between co-injected substances with pulverized coal into the blast furnace. ISIJ Int. 2014;54(12):2704–2712.
- Yamaguchi K, Ueno H, Tamura K. Maximum injection rate of pulverized coal into blast furnace through tuyeres with consideration of unburnt char. ISIJ Int. 1992;32(6):716–724.
- Guo B, Zulli P, Rogers H, et al. Three-dimensional simulation of flow and combustion for pulverised coal injection. ISIJ Int. 2005;45(9):1272–1281.
- Shen Y, Guo B, Yu A, et al. Three-dimensional modelling of coal combustion in blast furnace. ISIJ Int. 2008;48(6):777–786.
- Shen Y, Guo B, Yu A, et al. A three-dimensional numerical study of the combustion of coal blends in blast furnace. Fuel. 2009;88(2):255–263.
- Shen Y, Maldonado D, Guo B, et al. Computational fluid dynamics study of pulverized coal combustion in blast furnace raceway. Ind. Eng. Chem. Res. 2009;48(23):10314–10323.
- Shen Y, Guo B, Yu A, et al. Model study of the effects of coal properties and blast conditions on pulverized coal combustion. ISIJ Int. 2009;49(6):819–826.
- de Deus Vieira DS, Lemos LR, da Silva Pereira GR. Effect of coaxial oxygen enrichment on three different coals and their blends. Ironmak Steelmak 2021;48(3):242–253.
- Shen Y, Guo B, Yu A, et al. Three-dimensional modelling of in-furnace coal/coke combustion in a blast furnace. Fuel. 2011;90(2):728–738.
- Shen Y, Yu A, Zulli P. CFD modelling and analysis of pulverized coal injection in blast furnace: an overview. Steel Res Int 2011;82(5), 532–542.
- Shen Y, Yu A, Zulli P. Compare pilot-scale and industry-scale models of pulverized coal combustion in an ironmaking blast furnace. 7th international symposium on multiphase flow, heat mass transfer and energy conversion. AIP Conf Proc. 2013;1547(1):564–571.
- Shen Y, Yu A, Austin P, et al. CFD study of in-furnace phenomena of pulverised coal injection in blast furnace: effects of operating conditions. Powder Tech. 2012;223:27–38.
- Liao J, Yu A, Li Y, et al. Comparing the performance of a black coal and an upgraded brown coal by briquetting in ironmaking blast furnace. 11st international conference on CFD in the minerals and process industries.
- Liu Y, Shen Y. A combined experimental and numerical study of the charcoal injection in a blast furnace: effect of biomass pretreatment. Energy Fuels. 2020;34(1):827–841.
- Liu Y, Shen Y. Computational fluid dynamics study of biomass combustion in a simulated ironmaking blast furnace: effect of the particle shape. Energy Fuels. 2018;32(4):4372–4381.
- Liu Y, Shen Y. Three-dimensional modelling of charcoal combustion in an industrial scale blast furnace. Fuel. 2019;258:116088.
- Wijayanta AT, Saiful Alam M, Nakaso K, et al. Numerical study on pulverized biochar injection in blast furnace. ISIJ Int. 2014;54(7):1521–1529.
- Wijayanta AT, Saiful Alam M, Nakaso K, et al. Combustibility of biochar injected into the raceway of a blast furnace. Fuel Process. Tech. 2014;117:53–59.
- Miao Z, Zhou Z, Yu A, et al. CFD-DEM simulation of raceway formation in an ironmaking blast furnace. Powder Tech. 2017;314:542–549.
- Cui J, Hou Q, Shen Y. CFD-DEM study of coke combustion in the raceway cavity of an ironmaking blast furnace. Powder Tech. 2020;362:539–549.
- Zhuo Y, Shen Y. Three-dimensional transient modelling of coal and coke co-combustion in the dynamic raceway of ironmaking blast furnaces. Appl Energy. 2020;261:114456.
- Gu M, Chen G, Zhang M, et al. Three-dimensional simulation of the pulverized coal combustion inside blast furnace tuyere. Appl. Math. Mod. 2010;34(11):3536–3546.
- Gu M, Zhang M, Selvarasu NKC, et al. Numerical analysis of pulverized coal combustion inside tuyere and raceway. Steel Res Int. 2008;79(1):17–24.
- ANSYS. ANSYS CFX-Solver theory guide. Canonsburg (PA): ANSYS Inc; 2016.
- Ranz W, Marshall W. Evaporation from drops. Chem Eng Prog 1952;48(3):141–146.
- Lockwood F, Shah N. A new radiation solution method for incorporation in general combustion prediction procedures. Symp (Int) Combus Inst. 1981;18(1):1405–1414.
- Ubhayakar SK, Stickler DB, Von Rosenberg CW, et al. Rapid devolatilization of pulverized coal in hot combustion gases. Symp (Int) Combus Inst. 1977;16(1):427–436.
- Magnussen BF, Hjertager BH. On mathematical modeling of turbulent combustion with special emphasis on soot formation and combustion. Symp (Int) Combus Inst. 1976;16(1):719–729.