Oxy-fuel combustion of pulverized fuels: Combustion fundamentals and modeling

Applied Energy

Volumn 162, Issue , 2016, Pages 742-762

  Yin, Chungen ^a   Yan, Jinyue ^b,c  

^a AALBORG UNIVERSITY   (Denmark)

^b ROYAL INSTITUTE OF TECHNOLOGY   (Sweden)

^c MÄLARDALEN UNIVERSITY   (Sweden)

Author keywords

Carbon capture and storage; CFD; Combustion chemistry; Oxy fuel combustion; Radiation; System performance

Indexed keywords

AIR; CARBON; CARBON CAPTURE; CARBON DIOXIDE; COMBUSTION; COMPUTATIONAL FLUID DYNAMICS; COST EFFECTIVENESS; FUEL STORAGE; HEAT RADIATION; MASS TRANSFER; PULVERIZED FUEL;

COMBUSTION CHEMISTRY; COMPUTATIONAL FLUID DYNAMICS MODELING; OXY-FUEL COMBUSTION TECHNOLOGY; OXYFUEL COMBUSTION; RESEARCH AND DEVELOPMENT; STATE-OF-THE ART REVIEWS; SYSTEM PERFORMANCE; TECHNOLOGICAL CHALLENGES;

FUELS;

CARBON DIOXIDE; COMBUSTION; COMPUTATIONAL FLUID DYNAMICS; COST ANALYSIS; HYDROGEN; NITROGEN; OXYGEN; PERFORMANCE ASSESSMENT; POWER PLANT; PULVERIZED FUEL ASH;

EID: 84946593349     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2015.10.149     Document Type: Review

References (200)

1. Buhre B.J.P., Elliott L.K., Sheng C.D., Gupta R.P., Wall T.F. Oxy-fuel combustion technology for coal-fired power generation. Prog Energy Combust Sci 2005, 31:283-307.
2. Wall T., Liu Y., Spero C., Elliott L., Khare S., Rathnam R., et al. An overview on oxyfuel coal combustion - state of the art research and technology development. Chem Eng Res Des 2009, 87:1003-1016.
3. Normann F., Andersson K., Leckner B., Johnsson F. Emission control of nitrogen oxides in the oxy-fuel process. Prog Energy Combust Sci 2009, 35:385-397.
4. Toftegaard M.B., Brix J., Jensen P.A., Glarborg P., Jensen A.D. Oxy-fuel combustion of solid fuels. Prog Energy Combust Sci 2010, 36:581-625.
5. Scheffknecht G., Al-Makhadmeh L., Schnell U., Maier J. Oxy-fuel coal combustion - a review of the current state-of-the-art. Int J Greenh Gas Control 2011, 55:516-535.
6. Chen L., Yong S.Z., Ghoniem A.F. Oxy-fuel combustion of pulverized coal: characterization, fundamentals, stabilization and CFD modeling. Prog Energy Combust Sci 2012, 38:156-214.
7. Yan J. Carbon capture and storage (CCS). Appl Energy 2015, 148:A1-A6.
8. Kitto J.B., Stultz S.C. Steam: its generation and use 2005, The Babcock & Wilcox Company, Ohio. 41st ed.
9. Cengel Y.A. Heat transfer: a practical approach 2003, McGraw-Hill, New York. 2nd ed.
10. Turns S.R. An introduction to combustion: concepts and applications 2000, McGraw-Hill, Singapore. 2nd ed.
11. Cabrejos F.J., Klinzing G.E. Pickup and saltation mechanisms of solid particles in horizontal pneumatic transport. Powder Technol 1994, 79:173-186.
12. Pitsch H. Large-eddy simulation of turbulent combustion. Annu Rev Fluid Mech 2006, 38:453-482.
13. Gicquel L.Y.M., Staffelbach G., Poinsot T. Large eddy simulations of gaseous flames in gas turbine combustion chambers. Prog Energy Combust Sci 2012, 38:782-817.
14. Holtmeyer M.L., Kumfer B.M., Axelbaum R.L. Effects of biomass particle size during cofiring under air-fired and oxyfuel conditions. Appl Energy 2012, 93:606-613.
15. Maxey M.R., Riley J.J. Equation of motion for a small rigid sphere in a nonuniform flow. Phys Fluids 1983, 26:883-889.
16. Lazaro B.J., Lasheras J.C. Particle dispersion in a turbulent, plane, free shear layer. Phys Fluids A 1989, 1:1035-1044.
17. Ranz W.E., Marshall W.R. Evaporation from drops. Part I. Chem Eng Process 1952, 48:141-146.
18. Chui E.H., Hughes P.M.J., Raithby G.D. Implementation of the finite volume method for calculating radiative transfer in a pulverized fuel flame. Combust Sci Technol 1993, 92:225-242.
19. Ansys Fluent. Theory guide and users guide. Ansys Inc. USA; 2014.
20. Hottel H.C., Sarofim A.F. Radiative transfer 1967, McGraw-Hill, New York.
21. Wang L., Endrud N.E., Turns S.R., D'Agostini M.D., Slavejkov A.G. A study of the influence of oxygen index on soot, radiation, and emission characteristics of turbulent jet flames. Combust Sci Technol 2002, 174:45-72.
22. 2 combustion. Fuel 2007, 86:656-668.
23. Andersson K., Johansson R., Johnsson F., Leckner B. Radiation intensity of propane-fired oxy-fuel flames: implications for soot formation. Energy Fuels 2008, 22:1535-1541.
24. Yin C., Johansen L.C.R., Rosendahl L., Kær S.K. A new weighted sum of gray gases model applicable to CFD modeling of oxy-fuel combustion: derivation, validation and implementation. Energy Fuels 2010, 24:6275-6282.
25. Hu Y., Yan J., Li H. Effects of flue gas recycle on oxy-coal power generation systems. Appl Energy 2012, 97:255-263.
26. Johansson R., Andersson K., Leckner B., Thunman H. Models for gaseous radiative heat transfer applied to oxy-fuel conditions in boilers. Int J Heat Mass Transf 2010, 53:220-230.
27. Krishnamoorthy G., Sami M., Orsino S., Perera A., Shahnam M., Huckaby E.D. Radiation modeling in oxy-fuel combustion scenarios. Int J Comput Fluid Dyn 2010, 24:69-82.
28. 2 molar ratio when modeling gaseous radiative heat transfer with the weighted-sum-of-grey-gases model. Combust Flame 2011, 158:893-901.
29. Kangwanpongpan T., França F.H.R., da Silva R.C., Schneider P.S., Krautz H.J. New correlations for the weighted-sum-of-gray-gases model in oxy-fuel conditions based on HITEMP 2010 database. Int J Heat Mass Transf 2012, 55:7419-7433.
30. Krishnamoorthy G. A new weighted-sum-of-gray-gases model for oxy-combustion scenarios. Int J Energy Res 2013, 37:1752-1763.
31. Yin C., Rosendahl L., Kær S.K. Chemistry and radiation in oxy-fuel combustion: a computational fluid dynamics modeling study. Fuel 2011, 90:2519-2529.
32. Hjärtstam S., Johansson R., Andersson K., Johnsson F. Computational fluid dynamics modeling of oxy-fuel flames: the role of soot and gas radiation. Energy Fuels 2012, 26:2786-2797.
33. Yin C. Nongragy-gas effects in modeling of large-scale oxy-fuel combustion processes. Energy Fuels 2012, 26:3349-3356.
34. Wang L., Haworth D.C., Turns S.R., Modest M.F. Interactions among soot, thermal radiation, and NOx emissions in oxygen-enriched turbulent nonpremixed flames: a computational fluid dynamics modeling study. Combust Flame 2005, 141:170-179.
35. Nikolopoulos N., Agranoitis M., Violidakis I., Karampinis E., Nikolopoulos A., et al. Parametric investigation of a renewable alternative for utilities adopting the co-firing lignite/biomass concept. Fuel 2013, 113:873-897.
36. Johansson R., Leckner B., Andersson K., Johnsson F. Influence of particle and gas radiation in oxy-fuel combustion. Int J Heat Mass Transf 2013, 65:143-152.
37. Bäckström D., Johansson R., Andersson K., Johnsson F., Clausen S., Fateev A. Measurement and modeling of particle radiation in coal flames. Energy Fuels 2014, 28:2199-2210.
38. Yin C. On gas and particle radiation in pulverized fuel combustion furnaces. Appl Energy 2015, 157:554-561.
39. Smith T.F., Shen Z.F., Friedman J.N. Evaluation of coefficients for the weighted sum of gray gases model. J Heat Transf-Trans ASME 1982, 104:602-608.
40. Yin C. Refined weighted sum of gray gases model for air-fuel combustion and its impacts. Energy Fuels 2013, 27:6287-6294.
41. Ma L., Gharebaghi M., Porter R., Pourkashanian M., Jones J.M., Williams A. Modeling methods for co-fired pulverised fuel furnaces. Fuel 2009, 88:2448-2454.
42. Al-Abbas A.H., Naser J., Dodds D. CFD modeling of air-fired and oxy-fuel combustion of lignite in a 100 KW furnace. Fuel 2011, 90:1778-1795.
43. Álvarez L., Gharebaghi M., Pourkashanian M., Williams A., Riaza J., Pevida C., et al. CFD modeling of oxy-coal combustion in an entrained flow reactor. Fuel Process Technol 2011, 92:1489-1497.
44. Álvarez L., Yin C., Riaza J., Pevida C., Pis J.J., Rubiera F. Oxy-coal combustion in an entrained flow reactor: application of specific char and volatile combustion and radiation models for oxy-firing conditions. Energy 2013, 62:255-268.
45. Zhang J., Prationo W., Zhang L., Zhang Z. Computational fluid dynamics modeling on the air-firing and oxy-fuel combustion of dried Victorian brown coal. Energy Fuels 2013, 27:4258-4269.
46. Álvarez L., Yin C., Riaza J., Pevida C., Pis J.J., Rubiera F. Biomass co-firing under oxy-fuel conditions: a computational fluid dynamics modeling study and experimental validation. Fuel Process Technol 2014, 120:22-33.
47. Lockwood F.C., Rizvi S.M., Shah N.G. Comparative predictive experience of coal firing. Proc Inst Mech Eng Part C - J Eng Mech Eng Sci 1986, 200:79-87.
48. Zhang J., Ito T., Ito S., Riechelmann D., Fujimori T. Numerical investigation of oxy-coal combustion in a large-scale furnace: non-gray effect of gas and role of particle radiation. Fuel 2015, 139:87-93.
49. Du X., Annamalai K. The transition of isolated coal particle. Combust Flame 1994, 97:339-354.
50. Zhang D.K., Wall T.F. Ignition of coal particles: the influence of experimental technique. Fuel 1994, 73:1114-1119.
51. Wendt C., Eigenbrod C., Moriue O., Rath H.J. A model for devolatilization and ignition of an axisymmetric coal particle. Proc Combust Inst 2002, 29:449-457.
52. Grotkjær T., Dam-Johansen K., Jensen A.D., Glarborg P. An experimental study of biomass ignition. Fuel 2003, 82:825-833.
53. Faúndez J., Arenillas A., Rubiera F., García X., Gordon A.L., Pis J.J. Ignition behavior of different rank coals in an entrained flow reactor. Fuel 2005, 84:2172-2177.
54. Molina A., Shaddix C.R. Ignition and devolatilization of pulverized bituminous coal particles during oxygen/carbon dioxide coal combustion. Proc Combust Inst 2007, 31:1905-1912.
55. Shaddix C.R., Molina A. Particle imaging of ignition and devolatilization of pulverized coal during oxy-fuel combustion. Proc Combust Inst 2009, 32:2091-2098.
56. Arias B., Pevida C., Rubiera F., Pis J.J. Effect of biomass blending on coal ignition and burnout during oxy-fuel combustion. Fuel 2008, 87:2753-2759.
57. 2. Energy Fuels 2008, 22:3756-3762.
58. Khare S., Wall T.F., Farida A.Z., Liu Y., Moghtaderi B., Gupta R.P. Factors influencing the ignition of flames from air-fired swirl pf burners retrofitted to oxy-fuel. Fuel 2008, 87:1042-1049.
59. Ponzio A., Senthoorselvan S., Yang W., Blasiak W., Eriksson O. Ignition of single coal particles in high-temperature oxidizers with various oxygen concentrations. Fuel 2008, 87:974-987.
60. 2 mixtures by thermo-gravimetric analysis. J Anal Appl Pyrol 2009, 85:521-528.
61. 2 mixtures in drop-tube furnace. Fuel 2010, 89:2703-2712.
62. Riaza J., Álvarez L., Gil M.V., Pevida C., Pis J.J., Rubiera F. Effect of oxy-fuel combustion with steam addition on coal ignition and burnout in an entrained flow reactor. Energy 2011, 36:5314-5319.
63. Riaza J., Gil M.V., Álvarez L., Pevida C., Pis J.J., Rubiera F. Oxy-fuel combustion of coal and biomass blends. Energy 2012, 41:429-435.
64. Zhang J., Kelly K.E., Eddings E.G., Wendt J.O.L. Ignition in 40 kW co-axial turbulent diffusion oxy-coal jet flames. Proc Combust Inst 2011, 33:3375-3382.
65. 2 atmospheres. Combust Flame 2012, 159:1253-1271.
66. 2 atmospheres. Combust Flame 2012, 159:3554-3568.
67. Jovanovic R., Rasuo B., Stefanovic P., Cvetinovic D., Swiatkowski B. Numerical investigation of pulverized coal jet flame characteristics under different oxy-fuel conditions. Int J Heat Mass Transf 2013, 58:654-662.
68. Momeni M., Yin C., Kær S.K., Hansen T.B., Jensen P.A., Glarborg P. Experimental study on effects of particle shape and operating conditions on combustion characteristics of single biomass particle. Energy Fuels 2013, 27:507-514.
69. Momeni M., Yin C., Kær S.K., Hvid S.L. Comprehensive study of ignition and combustion of single wooden particles. Energy Fuels 2013, 27:1061-1072.
70. Ahn S., Choi G., Kim D. The effect of wood biomass blending with pulverized coal on combustion characteristics under oxy-fuel condition. Biomass Bioenerg 2014, 71:144-154.
71. Riaza J., Khatami R., Levendis Y.A., Álvarez L., Gil M.V., Pevida C., et al. Single particle ignition and combustion of anthracite, semi-anthracite and bituminous coals in air and simulated oxy-fuel conditions. Combust Flame 2014, 161:1096-1108.
72. 2 atmosphere. Appl Energy 2014, 132:349-357.
73. 2O mixtures in a drop tube furnace using flame monitoring techniques. Proc Combust Inst 2015, 35:3629-3636.
74. Essenhigh R.H., Misra M.K., Shaw D.W. Ignition of coal particles: a review. Combust Flame 1989, 77:3-30.
75. Yu J., Lucas J.A., Wall T.F. Formation of the structure of chars during devolatilization of pf pulverized coal and its thermoproperties: a review. Prog Energy Combust Sci 2007, 33:135-170.
76. Badzioch S., Hawksley P.G.W. Kinetics of thermal decomposition of pulverized coal particles. Ind Eng Chem Process Des Dev 1970, 9:521-530.
77. Kobayashi H., Howard J.B., Sarofim A.F. Coal devolatilization at high temperatures. Proc Combust Inst 1976, 16:411-425.
78. Grant D.M., Pugmire R.J., Fletcher T.H., Kerstein A.R. Chemical percolation model of coal devolatilization using percolation lattice statistics. Energy Fuels 1989, 3:175-186.
79. Fletcher T.H., Kerstein A.R., Pugmire R.J., Grant D.M. Chemical percolation model for devolatilization. 2. Temperature and heating rate effects on product yields. Energy Fuels 1990, 4:54-60.
80. 13C NMR data to predict effects of coal type. Energy Fuels 1992, 6:414-431.
81. Solomon P.R., Hamblen D.G., Carangelo R.M., Serio M.A., Deshpande G.V. General model of coal devolatilization. Energy Fuels 1988, 2:405-422.
82. 2 atmospheres. Fuel 2012, 101:23-37.
83. Lemaire R., Menage D., Menanteau S., Harion J.L. Experimental study and kinetic modeling of pulverized coal devolatilization under air and oxycombustion conditions at a high heating rate. Fuel Process Technol 2014, 128:183-190.
84. Advanced Fuel Research (AFR), Inc. FG-DVC Model; 2009 <>. http://www.afrinc.com/products/fgdvc/.
85. Álvarez L., Gharebaghi M., Jones J.M., Pourkashanian M., Williams A., Riaza J., et al. Numerical investigation of NO emissions from an entrained flow reactor under oxy-coal conditions. Fuel Process Technol 2012, 93:53-64.
86. Álvarez L., Gharebaghi M., Jones J.M., Pourkashanian M., Williams A., Riaza J., et al. CFD modeling of oxy-coal combustion: prediction of burnout, volatile and NO precursors release. Appl Energy 2013, 104:653-665.
87. Black S., Szuhánszki J., Pranzitelli A., Ma L., Stanger P.J., Ingham D.B., et al. Effects of firing coal and biomass under oxy-fuel conditions in a power plant boiler using CFD modeling. Fuel 2013, 113:780-786.
88. 2) conditions. Fuel Process Technol 2009, 90:797-802.
89. 2 atmospheres. Fuel 2010, 89:3373-3380.
90. Gil M.V., Riaza J., Álvarez L., Pevida C., Pis J.J., Rubiera F. Oxy-fuel combustion kinetics and morphology of coal chars obtained in N2 and CO2 atmospheres in an entrained flow reactor. Appl Energy 2012, 91:67-74.
91. 2 atmospheres. Energy 2012, 48:510-518.
92. Wang C., Zhang X., Liu Y., Che D. Pyrolysis and combustion characteristics of coals in oxyfuel combustion. Appl Energy 2012, 97:264-273.
93. Yin C., Kær S.K., Rosendahl L., Hvid S.L. Co-firing straw with coal in a swirl-stabilized dual-feed burner: modeling and experimental validation. Bioresour Technol 2010, 101:4169-4178.
94. Westbrook C.K., Dryer F.L. Simplified reaction-mechanisms for the oxidation of hydrocarbon fuels in flames. Combust Sci Technol 1981, 27:31-43.
95. Westbrook C.K., Dryer F.L. Chemical kinetic modeling of hydrocarbon combustion. Prog Energy Combust Sci 1984, 10:1-57.
96. Jones W.P., Lindstedt R.P. Global reaction schemes for hydrocarbon combustion. Combust Flame 1988, 73:233-249.
97. x formation. Combust Flame 2001, 2001(125):778-787.
98. 2 concentration in oxy-fuel combustion of methane. Energy Fuels 2008, 22:291-296.
99. 2O on the oxidation of CO: experiments and modeling. Proc Combust Inst 2011, 33:317-323.
100. 2 chemical effects on CO formation in oxy-fuel diffusion flames using detailed, quasi-global, and global reaction mechanisms. Combust Sci Technol 2014, 186:829-848.
101. x. Energy Fuels 2009, 23:725-734.
102. Andersen J., Rasmussen C.L., Giselsson T., Glarborg P. Global combustion mechanisms for use in CFD modeling under oxy-fuel conditions. Energy Fuels 2009, 23:1379-1389.
103. Marinov N.M., Westbrook C.K., Pitz W.J. Detailed and global chemical kinetics model for hydrogen. Transport phenomena in combustion 1996, Taylor and Francis, Washington (DC). S.H. Chan (Ed.).
104. 2 gasification reaction on oxy-combustion of pulverized coal char. Proc Combust Inst 2011, 33:1699-1706.
105. 2 reaction. Fuel Process Technol 2012, 102:156-165.
106. 2 atmospheres. Fuel 2014, 124:190-201.
107. 2) atmospheres. Combust Flame 2013, 160:2559-2572.
108. 2 and steam gasification reactions on the oxy-combustion of pulverized coal char. Combust Flame 2012, 159:3437-3447.
109. 2 atmospheres. Fuel 2011, 90:2224-2239.
110. Geier M., Shaddix C.R., Davis K.A., Shim H.S. On the use of single-film models to describe the oxy-fuel combustion of pulverized coal char. Appl Energy 2012, 93:675-679.
111. Hecht E.S., Shaddix C.R., Lighty J.S. Analysis of the errors associated with typical pulverized coal char combustion modeling assumptions for oxy-fuel combustion. Combust Flame 2013, 160:1499-1509.
112. Tognotti L., Longwell J.P., Sarofim A.F. The products of the high temperature oxidation of a single char particle in an electrodynamic balance. Proc Combust Inst 1990, 23:1207-1213.
113. Gonzalo-Tirado C., Jiménez S. Detailed analysis of the CO oxidation chemistry around a coal char particle under conventional and oxy-fuel combustion conditions. Combust Flame 2015, 162:478-485.
114. Kühnemuth D., Normann F., Andersson K., Johnsson F. On the carbon monoxide formation in oxy-fuel combustion - contribution by homogenous and heterogeneous reactions. Int J Greenh Gas Control 2014, 25:31-41.
115. Yu J., Zhou K., Ou W. Mass transfer coefficients considering effects of steam in oxy-fuel combustion of coal char. Fuel 2013, 111:48-56.
116. 2 atmospheres. Energy Fuels 2013, 27:3454-3459.
117. Glarborg P., Jensen A.D., Johnsson J.E. Fuel nitrogen conversion in solid fuel fired systems. Prog Energy Combust Sci 2003, 29:89-113.
118. Andersson K., Normann F., Johnsson F., Leckner B. NO emission during oxy-fuel combustion of lignite. Ind Eng Chem Res 2008, 47:1835-1845.
119. 2. Energy 1997, 22:207-215.
120. x emissions in oxycoal combustion. Fuel 2011, 90:1604-1611.
121. Mendiara T., Glarborg P. Reburn chemistry in oxy-fuel combustion of methane. Energy Fuels 2009, 23:3565-3572.
122. Mendiara T., Glarborg P. Ammonia chemistry in oxy-fuel combustion of methane. Combust Flame 2009, 156:1937-1949.
123. 2 combustion. Combust Flame 2011, 158:1255-1263.
124. 2O. Proc Combust Inst 2005, 30:2169-2175.
125. Aarna I., Suuberg E.M. The role of carbon monoxide in the NO-carbon reaction. Energy Fuels 1999, 13:1145-1153.
126. López D., Calo J. The NO-carbon reaction: the influence of potassium and CO on reactivity and populations of oxygen surface complexes. Energy Fuels 2007, 21:1872-1877.
127. Sun S., Cao H., Chen H., Wang X., Qian J., Wall T. Experimental study of influence of temperature on fuel-N conversion and recycle NOx reduction in oxyfuel combustion. Proc Combust Inst 2011, 33:1731-1738.
128. x formation during oxy-fuel combustion of pulverized coal. Proc Combust Inst 2011, 33:1723-1730.
129. Wang G., Zander R., Costa M. Oxy-fuel combustion characteristics of pulverized-coal in a drop tube furnace. Fuel 2014, 115:452-460.
130. Yin C., Rosendahl L., Kær S.K. Grate-firing of biomass for heat and power production. Prog Energy Combust Sci 2008, 34:725-754.
131. Hill S.C., Smoot L.D. Modeling of nitrogen oxides formation and destruction in combustion systems. Prog Energy Combust Sci 2000, 26:417-458.
132. 2 formation from fuel nitrogen. Proc Combust Inst 1975, 15:1093-1102.
133. Lockwood F.C., Romo-Millares C.A. Mathematical modeling of fuel-NO emissions from PF burners. J Inst Energy 1992, 65:144-152.
134. Chui E.H., Douglas M.A., Tan Y. Modeling of oxy-fuel combustion for a western Canadian sub-bituminous coal. Fuel 2003, 82:1201-1210.
135. Chui E.H., Majeski A.J., Douglas M.A., Tan Y., Thambimuthu K.V. Numerical investigation of oxy-coal combustion to evaluate burner and combustor design concepts. Energy 2004, 29:1285-1296.
136. AVL Fire CFD Solver v 8.5 manual. A-8020 Gras, Austria; 2008 <>. http://www.avl.com.
137. 2 atmosphere. Combust Flame 2008, 155:605-618.
138. th test facility using RANS and LES: a validation study. Energy Fuels 2012, 26:4783-4798.
139. Kangwanpongpan T., da Silva R.C., Krautz H.J. Prediction of oxy-coal combustion through an optimized weighted sum of gray gases model. Energy 2012, 41:244-251.
140. x reduction mechanism in oxy-fuel combustion. Energy Fuels 2010, 24:131-135.
141. Hu Y., Yan J. Numerical simulation of radiation intensity of oxy-coal combustion with flue gas recirculation. Int J Greenh Gas Control 2013, 17:473-480.
142. Edge P., Gubba S.R., Ma L., Porter P., Pourkashanian M., Williams A. LES modeling of air and oxy-fuel pulverised coal combustion - impact on flame properties. Proc Combust Inst 2011, 33:2709-2716.
143. Bhuiyan A.A., Naser J. Numerical modeling of oxy fuel combustion, the effect of radiative and convective heat transfer and burnout. Fuel 2015, 139:268-284.
144. Bhuiyan A.A., Naser J. Computational modeling of co-firing of biomass with coal under oxy-fuel condition in a small scale furnace. Fuel 2015, 143:455-466.
145. Gharebaghi M., Irons R.M.A., Ma L., Pourkashaniana M., Pranzitelli A. Large eddy simulation of oxy-coal combustion in an industrial combustion test facility. Int J Greenh Gas Control 2011, 5S:S100-10.
146. Naredi P. Coal combustion in O2/CO2 medium for power generation: Numerical modeling of char burnout, NOx and CO emissions. PhD Thesis. The Pennsylvania State University; 2009.
147. Jovanovic R., Milewska A., Swiatkowski B., Goanta A., Spliethoff H. Numerical investigation of influence of homogeneous/heterogeneous ignition/combustion mechanisms on ignition point position during pulverized coal combustion in oxygen enriched and recycled flue gases atmosphere. Int J Heat Mass Transf 2011, 54:921-931.
148. Zhang J., Dai B., Meng Y., Wu X., Zhang J., Zhang X., et al. Pilot-scale experimental and CFD modeling investigations of oxy-fuel combustion of Victorian brown coal. Fuel 2015, 144:111-120.
149. Nikolopoulos N., Nikolopoulos A., Karampinis E., Grammelis P., Kakaras E. Numerical investigation of the oxy-fuel combustion in large scale boilers adopting the ECO-scrub technology. Fuel 2011, 90:198-214.
150. Al-Abbas A.H., Naser J., Dodds D. CFD modeling of air-fired and oxy-fuel combustion in a large-scale furnace at Loy Yang A brown coal power station. Fuel 2012, 102:646-665.
151. Hu Y., Li H., Yan J. Numerical investigation of heat transfer characteristics in utility boilers of oxy-coal combustion. Appl Energy 2014, 130:543-551.
152. e tangentially fired boiler. Fuel 2015, 140:660-668.
153. Gao H., Runstedtler A., Majeski A., Yandon R., Zanganeh K., Shafeen A. Reducing the recycle flue gas rate of an oxy-fuel utility power boiler. Fuel 2015, 140:578-589.
154. Andersson K. Characterization of oxy-fuel flames - their composition, temperature and radiation. Chalmers University of Technology. PhD Thesis, Göteborg; 2007.
155. Smart J.P., Patel R., Riley G.S. Oxy-fuel combustion of coal and biomass, the effect on radiative and convective heat transfer and burnout. Combust Flame 2010, 157:2230-2240.
156. Smart J.P., O'Nions P., Riley G.S. Radiation and convective heat transfer, and burnout in oxy-coal combustion. Fuel 2010, 89:2468-2476.
157. Galletti C., Coraggio G., Tognotti L. Numerical investigation of oxy-natural-gas combustion in a semi-industrial furnace: validation of CFD sub-models. Fuel 2013, 109:445-460.
158. Muto M., Watanabe H., Kurose R., Komori S., Balusamy S., Hochgreb S. Large-eddy simulation of pulverized coal jet flame - effect of oxygen concentration on NOx formation. Fuel 2015, 142:152-163.
159. Prieler R., Demuth M., Spoljaric D., Hochenauer C. Numerical investigation of the steady flamelet approach under different combustion environments. Fuel 2015, 140:731-743.
160. Rosendahl L.A., Yin C., Kær S.K., Friborg K., Overgaard P. Physical characterization of biomass fuels prepared for suspension firing in utility boilers for CFD modeling. Biomass Bioenerg 2007, 31:318-325.
161. Baxter L. Biomass-coal co-combustion: opportunity for affordable renewable energy. Fuel 2005, 84:1295-1302.
162. Roberts K., Yan Y., Carter R.M. On-line sizing and velocity measurement of particles in pneumatic pipelines through digital imaging. J Phys: Conf Ser 2007, 85:012019.
163. Yin C., Rosendahl L., Kær S.K., Sørensen H. Modeling the motion of cylindrical particles in a nonuniform flow. Chem Eng Sci 2003, 58:3489-3498.
164. Yin C., Rosendahl L., Kær S.K., Condra T. Use of numerical modeling in design for co-firing biomass in wall-fired burners. Chem Eng Sci 2004, 59:3281-3292.
165. 2 capture. Handbook of clean energy systems 2015, vol. 2. Wiley. J. Yan (Ed.).
166. IPCC. Special report on carbon dioxide capture and storage. Cambridge: Cambridge University Press; 2005.
167. IEA. Technology roadmap - carbon capture and storage; 2009.
168. Shah K., Moghtaderi B., Zanganeh J., Wall T. Integration options for novel chemical looping air separation (ICLAS) process for oxygen production in oxy-fuel coal fired power plants. Fuel 2013, 107:356-370.
169. Aneke M., Wang M. Potential for improving the energy efficiency of cryogenic air separation unit (ASU) using binary heat recovery cycles. Appl Therm Eng 2015, 81:223-231.
170. Castillo R. Thermodynamic analysis of a hard coal oxyfuel power plant with high temperature three-end membrane for air separation. Appl Energy 2011, 88:1480-1493.
171. Smith A.R., Klosek J. A review of air separation technologies and their integration with energy conversion processes. Fuel Process Technol 2001, 70:115-134.
172. Hu Y., Li X., Li H., Yan J. Peak and off-peak operations of the air separation unit in oxy-coal combustion power generation systems. Appl Energy 2013, 112:747-754.
173. Arias B., Criado Y.A., Sanchez-Biezma A., Abanades J.C. Oxy-fired fluidized bed combustors with a flexible power output using circulating solids for thermal energy storage. Appl Energy 2014, 132:127-136.
174. 2 capture. Appl Energy 2012, 90:113-121.
175. 2 recovery. Energ Convers Manage 1992, 33:379-386.
176. 2 capture and storage system. Appl Energy 2009, 86:202-213.
177. 2 capture and storage processes. Appl Energy 2009, 86:826-836.
178. 2 capture and storage (CCS) processes. Appl Energy 2009, 86:2760-2770.
179. 2O. Int J Energ Res 2006, 30:135-148.
180. 2 conditioning and transport: review of available experimental data and theoretical models. Appl Energy 2011, 88:3567-3579.
181. 2 mixtures: review of experimental data and theoretical models. Int J Greenh Gas Control 2011, 5:1119-1139.
182. Yan J, Anheden M, Bernstone C, Liljemark S, Pettersson H, Li H, et al. Impacts of non-condensable components on CO2 compression/purification, pipeline transport and geological storage. In: 1st IEA oxyfuel combustion conference, Cottbus, Germany, September 8-11, 2009.
183. Wall T., Stanger R., Liu Y. Gas cleaning challenges for coal-fired oxy-fuel technology with carbon capture, and storage. Fuel 2013, 108:85-90.
184. 2 capture. Appl Energy 2011, 88:1187-1196.
185. Park S.K., Ahn J.H., Kim T.S. Performance evaluation of integrated gasification solid oxide fuel cell/gas turbine systems including carbon dioxide capture. Appl Energy 2011, 88:2976-2987.
186. Lyngfelt A. Chemical-looping combustion of solid fuels - status of development. Appl Energy 2014, 113:1869-1873.
187. 2 capture in power plants. Int J Greenh Gas Control 2015, 40:55-125.
188. th oxyfuel pilot plant in Schwarze Pumpe. Energy Procedia 2011, 4:941-950.
189. National Coal Council. Fossil forward: revitalizing CCS bringing scale and speed to CCS deployment; 2015.
190. Global CCS Institute. The costs of CCS and other low-carbon technologies in the United States: 2015 update; 27 July 2015.
191. Davidson RM, Santos SO, Oxyfuel combustion of pulverised coal. IEA Greenhouse Gas R&D Programme (IEAGHG); 24 August 2010.
192. Borgert K.J., Rubin E.S. Oxyfuel combustion: technical and economic considerations for the development of carbon capture from pulverized coal power plants. Energy Procedia 2013, 37:1291-1300.
193. Oboirien B.O., North B.C., Kleyn T. Techno-economic assessments of oxy-fuel technology for South African coal-fired power stations. Energy 2014, 66:550-555.
194. Global CCS Institute. Toward a common method of cost estimation for CO2 capture and storage at fossil fuel power plants; 2013.
195. 2 mixtures: a case study of Victorian brown coal. Proc Combust Inst 2011, 33:2795-2802.
196. Fryda L., Sobrino C., Glazer M., Bertrand C., Cieplik M. Study of ash deposition during coal combustion under oxyfuel conditions. Fuel 2012, 92:308-317.
197. Li G., Li S., Dong M., Yao Q., Guo C.Y., Axelbaum R.L. Comparison of particulate formation and ash deposition under oxy-fuel and conventional pulverized coal combustions. Fuel 2013, 106:544-551.
198. 2-char of Chinese coals. Proc Combust Inst 2013, 34:2383-2392.
199. Li W., Wang L., Qiao Y., Lin J.Y., Wang M., Chang L. Effect of atmosphere on the release behavior of alkali and alkaline earth metals during coal oxy-fuel combustion. Fuel 2015, 139:164-170.
200. Morris W.J., Yu D., Wendt J.O.L. Soot, unburnt carbon and ultrafine particle emissions from air- and oxy-coal flames. Proc Combust Inst 2011, 33:3415-3421.