Modeling of single coal particle combustion in O2/N2 and O2/CO2 atmospheres under fluidized bed condition
Received date: 15 Sep 2019
Accepted date: 08 Apr 2020
Published date: 15 Mar 2021
Copyright
A one-dimensional transient single coal particle combustion model was proposed to investigate the characteristics of single coal particle combustion in both O2/N2 and O2/CO2 atmospheres under the fluidized bed combustion condition. The model accounted for the fuel devolatilization, moisture evaporation, heterogeneous reaction as well as homogeneous reactions integrated with the heat and mass transfer from the fluidized bed environment to the coal particle. This model was validated by comparing the model prediction with the experimental results in the literature, and a satisfactory agreement between modeling and experiments proved the reliability of the model. The modeling results demonstrated that the carbon conversion rate of a single coal particle (diameter 6 to 8 mm) under fluidized bed conditions (bed temperature 1088 K) in an O2/CO2 (30:70) atmosphere was promoted by the gasification reaction, which was considerably greater than that in the O2/N2 (30:70) atmosphere. In addition, the surface and center temperatures of the particle evolved similarly, no matter it is under the O2/N2 condition or the O2/CO2 condition. A further analysis indicated that similar trends of the temperature evolution under different atmospheres were caused by the fact that the strong heat transfer under the fluidized bed condition overwhelmingly dominated the temperature evolution rather than the heat release of the chemical reaction.
Key words: coal; oxy-fuel; fluidized bed; combustion; simulation
Xiehe YANG , Yang ZHANG , Daoyin LIU , Jiansheng ZHANG , Hai ZHANG , Junfu LYU , Guangxi YUE . Modeling of single coal particle combustion in O2/N2 and O2/CO2 atmospheres under fluidized bed condition[J]. Frontiers in Energy, 2021 , 15(1) : 99 -111 . DOI: 10.1007/s11708-020-0685-0
| 1 |
Wang H, He J. China’s pre-2020 CO2 emission reduction potential and its influence. Frontiers in Energy, 2019, 13(3): 571–578
|
| 2 |
Wang W, Li Z, Lyu J, Zhang H, Yue G, Ni W. An overview of the development history and technical progress of China’s coal-fired power industry. Frontiers in Energy, 2019, 13(3): 417–426
|
| 3 |
Kanniche M, Gros-Bonnivard R, Jaud P, Valle-Marcos J, Amann J M, Bouallou C. Pre-combustion, post-combustion and oxy-combustion in thermal power plant for CO2 capture. Applied Thermal Engineering, 2010, 30(1): 53–62
|
| 4 |
Kunze C, Spliethoff H. Assessment of oxy-fuel, pre- and post-combustion-based carbon capture for future IGCC plants. Applied Energy, 2012, 94: 109–116
|
| 5 |
Leung D Y C, Caramanna G, Maroto-Valer M M. An overview of current status of carbon dioxide capture and storage technologies. Renewable & Sustainable Energy Reviews, 2014, 39: 426–443
|
| 6 |
Kazanc F, Khatami R, Manoel Crnkovic P, Levendis Y A. Emissions of NOx and SO2 from coals of various ranks, bagasse, and coal-bagasse blends burning in O2/N2 and O2/CO2 environments. Energy & Fuels, 2011, 25(7): 2850–2861
|
| 7 |
Khatami R, Stivers C, Joshi K, Levendis Y A, Sarofim A F. Combustion behavior of single particles from three different coal ranks and from sugar cane bagasse in O2/N2 and O2/CO2 atmospheres. Combustion and Flame, 2012, 159(3): 1253–1271
|
| 8 |
Khatami R, Stivers C, Levendis Y A. Ignition characteristics of single coal particles from three different ranks in O2/N2 and O2/CO2 atmospheres. Combustion and Flame, 2012, 159(12): 3554–3568
|
| 9 |
Riaza J, Khatami R, Levendis Y A, Álvarez L, Gil M V, Pevida C, Rubiera F, Pis J J. Single particle ignition and combustion of anthracite, semi-anthracite and bituminous coals in air and simulated oxy-fuel conditions. Combustion and Flame, 2014, 161(4): 1096–1108
|
| 10 |
Piotrowska P, Zevenhoven M, Davidsson K, Hupa M, Åmand L E, Barišić V, Coda Zabetta E. Fate of alkali metals and phosphorus of rapeseed cake in circulating fluidized bed boiler. Part 2: cocombustion with coal. Energy & Fuels, 2010, 24(8): 4193–4205
|
| 11 |
Piotrowska P, Zevenhoven M, Davidsson K, Hupa M, Åmand L E, Barišić V, Coda Zabetta E. Fate of alkali metals and phosphorus of rapeseed cake in circulating fluidized bed boiler. Part 1: cocombustion with wood. Energy & Fuels, 2010, 24(1): 333–345
|
| 12 |
Leckner B, Gómez-Barea A. Oxy-fuel combustion in circulating fluidized bed boilers. Applied Energy, 2014, 125: 308–318
|
| 13 |
Seddighi K S, Pallarès D, Normann F, Johnsson F. Progress of combustion in an oxy-fuel circulating fluidized-bed furnace: measurements and modeling in a 4 MWth boiler. Energy & Fuels, 2013, 27(10): 6222–6230
|
| 14 |
Tan Y, Jia L, Wu Y, Anthony E J. Experiences and results on a 0.8 MWth oxy-fuel operation pilot-scale circulating fluidized bed. Applied Energy, 2012, 92: 343–347
|
| 15 |
Duan L, Sun H, Zhao C, Zhou W, Chen X. Coal combustion characteristics on an oxy-fuel circulating fluidized bed combustor with warm flue gas recycle. Fuel, 2014, 127: 47–51
|
| 16 |
Varol M, Symonds R, Anthony E J, Lu D, Jia L, Tan Y. Emissions from co-firing lignite and biomass in an oxy-fired CFBC. Fuel Processing Technology, 2018, 173: 126–133
|
| 17 |
Hernberg R, Stenberg J, Zethraus B. Simultaneous in situ measurement of temperature and size of burning char particles in a fluidized bed furnace by means of fiberoptic pyrometry. Combustion and Flame, 1993, 95(1-2): 191–205
|
| 18 |
Joutsenoja T, Heino P, Hernberg R, Bonn B. Pyrometric temperature and size measurements of burning coal particles in a fluidized bed combustion reactor. Combustion and Flame, 1999, 118(4): 707–717
|
| 19 |
Bu C, Leckner B, Chen X, Pallarès D, Liu D, Gómez-Barea A. Devolatilization of a single fuel particle in a fluidized bed under oxy-combustion conditions. Part A: experimental results. Combustion and Flame, 2015, 162(3): 797–808
|
| 20 |
Lupion M, Alvarez I, Otero P, Kuivalainen R, Lantto J, Hotta A, Hack H. 30 MWth CIUDEN oxy-cfb boiler–first experiences. Energy Procedia, 2013, 37: 6179–6188
|
| 21 |
Lyu J, Yang H, Ling W, Nie L, Yue G, Li R, Chen Y, Wang S. Development of a supercritical and an ultra-supercritical circulating fluidized bed boiler. Frontiers in Energy, 2019, 13(1): 114–119
|
| 22 |
Garcia-Gutierrez L, Hernández-Jiménez F, Cano-Pleite E, Soria-Verdugo A. Improvement of the simulation of fuel particles motion in a fluidized bed by considering wall friction. Chemical Enginee-ring Journal, 2017, 321: 175–183
|
| 23 |
Zhu S, Zhang M, Huang Y, Wu Y, Yang H, Lyu J, Gao X, Wang F, Yue G. Thermodynamic analysis of a 660 MW ultra-supercritical CFB boiler unit. Energy, 2019, 173: 352–363
|
| 24 |
Saxena S C. Devolatilization and combustion characteristics of coal particles. Progress in Energy and Combustion Science, 1990, 16(1): 55–94
|
| 25 |
Solomon P R, Serio M A, Suuberg E M. Coal pyrolysis: experiments, kinetic rates and mechanisms. Progress in Energy and Combustion Science, 1992, 18(2): 133–220
|
| 26 |
Chern J S, Hayhurst A N. Does a large coal particle in a hot fluidised bed lose its volatile content according to the shrinking core model? Combustion and Flame, 2004, 139(3): 208–221
|
| 27 |
Scala F, Chirone R. Fluidized bed combustion of single coal char particles at high CO2 concentration. Chemical Engineering Journal, 2010, 165(3): 902–906
|
| 28 |
Scala F, Chirone R. Combustion of single coal char particles under fluidized bed oxyfiring conditions. Industrial & Engineering Chemistry Research, 2010, 49(21): 11029–11036
|
| 29 |
Guedea I, Pallarès D, Díez L I, Johnsson F. Conversion of large coal particles under O2/N2 and O2/CO2 atmospheres—experiments and modeling. Fuel Processing Technology, 2013, 112: 118–128
|
| 30 |
Bu C, Leckner B, Chen X, Gómez-Barea A, Liu D, Pallarès D. Devolatilization of a single fuel particle in a fluidized bed under oxy-combustion conditions. Part B: modeling and comparison with measurements. Combustion and Flame, 2015, 162(3): 809–818
|
| 31 |
Salinero J, Gómez-Barea A, Fuentes-Cano D, Leckner B. Measurement and theoretical prediction of char temperature oscillation during fluidized bed combustion. Combustion and Flame, 2018, 192: 190–204
|
| 32 |
Nikrityuk P, Meyer B. Gasification Processes: Modeling and Simulation. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA, 2014
|
| 33 |
Bhatia S, Perlmutter D. A random pore model for fluid-solid reactions: I. Isothermal, kinetic control. AIChE Journal, 1980, 26(3): 379–386
|
| 34 |
Chern J S, Hayhurst A N. A model for the devolatilization of a coal particle sufficiently large to be controlled by heat transfer. Combustion and Flame, 2006, 146(3): 553–571
|
| 35 |
Loison R, Chauvin F. Rapid coal pyrolysis. Chemical Industry (Paris), 1964, 91 (in French)
|
| 36 |
Rowe P N, Clayton K T, Lewis J B. Heat mass transfer from single sphere in an extensive flowing fluid. Transactions of the Institution of Chemical Engineers, 1965, 43: 14–31
|
| 37 |
Herrin J M, Deming D. Thermal conductivity of US coals. Journal of Geophysical Research–Solid Earth, 1996, 101(B11): 25381–25386
|
| 38 |
Maloney D J, Monazam E R, Woodruff S D, Lawson L O. Measurements and analysis of temperature histories and size changes for single carbon and coal particles during the early stages of heating and devolatilization. Combustion and Flame, 1991, 84(1–2): 210–220
|
| 39 |
Duan L, Li L, Liu D, Zhao C. Fundamental study on fuel-staged oxy-fuel fluidized bed combustion. Combustion and Flame, 2019, 206: 227–238
|
/
| 〈 |
|
〉 |