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Combustion Science and Technology Volume 45, 1986 - Issue 5-6
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Original Articles

Heat and Mass Transfer in the Vicinity of a Devolatilizing Coal Particle

Steven P. Dwyer Sandia National Laboratories, Livermore, CA, 94550
,
Musarra. THOMAS Dwyer Sandia National Laboratories, Livermore, CA, 94550
,
H. Fletcher Dwyer Sandia National Laboratories, Livermore, CA, 94550
,
Stephen Niksa Dwyer Sandia National Laboratories, Livermore, CA, 94550
&
Harry A. Dwyer Sandia National Laboratories, Livermore, CA, 94550
Pages 289-307 | Received 11 Feb 1985, Accepted 04 Jun 1985, Published online: 25 Apr 2007

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Chong Pyo Cho, Sangpil Jo, Ho Young Kim & SamS. Yoon. (2007) Numerical Studies on Combustion Characteristics of Interacting Pulverized Coal Particles at Various Oxygen Concentration. Numerical Heat Transfer, Part A: Applications 52:12, pages 1101-1122.
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ROBERTE. PECK, PETER GLARBORG & JANE. JOHNSSON. (1991) Kinetic Modeling of Fuel-Nitrogen Conversion in One-Dimensional, Pulverized-Coal Flames. Combustion Science and Technology 76:1-3, pages 81-109.
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Andrew P. Richards, Colson Johnson & Thomas H. Fletcher. (2019) Correlations of the Elemental Compositions of Primary Coal Tar and Char. Energy & Fuels 33:10, pages 9520-9537.
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Shota AKAOTSU, Kengo ISHIMODA, Yasuhiro SAITO, Yohsuke MATSUSHITA & Hideyuki AOKI. (2019) Extending Semi-parallel Reaction Model of Pulverized Coal Particle to Various Coal Types. Journal of the Japan Institute of Energy 98:3, pages 35-43.
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André Bader, Vinoj Kurian, Robin Schmidt, Petr Nikrityuk, Bernd Meyer & Rajender Gupta. (2016) Advanced subgrid model for the gasification of Athabasca asphaltene in entrained-flow reactors. International Journal of Thermal Sciences 102, pages 329-341.
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Valdeci José Costa, Viktor Georgevith Krioukov & Clóvis Raimundo Maliska. (2014) Numerical simulation of pulverized wet coal combustion using detailed chemical kinetics. Journal of the Brazilian Society of Mechanical Sciences and Engineering 36:4, pages 661-672.
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Jaakko Saastamoinen & Antti Tourunen. (2011) Model for Char Combustion, Particle Size Distribution, and Inventory in Air and Oxy-fuel Combustion in Fluidized Beds. Energy & Fuels 26:1, pages 407-416.
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F.J. Higuera. (2008) Combustion of a coal char particle in a stream of dry gas. Combustion and Flame 152:1-2, pages 230-244.
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Shuyan Wang, Huilin Lu, Yunhua Zhao, Reza Mostofi, Ho Young Kim & Lijie Yin. (2007) Numerical study of coal particle cluster combustion under quiescent conditions. Chemical Engineering Science 62:16, pages 4336-4347.
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Yunhua Zhao, Ho Young Kim & Sam S. Yoon. (2007) Transient group combustion of the pulverized coal particles in spherical cloud. Fuel 86:7-8, pages 1102-1111.
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Carlos A. Gurgel Veras, Jaakko Saastamoinen & João Andrade De CarvalhoJr.Jr.. (1998) Effect of particle size and pressure on the conversion of fuel N to no in the boundary layer during devolatilization stage of combustion. Symposium (International) on Combustion 27:2, pages 3019-3025.
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Jaakko J. Saastamoinen, Martti J. Aho, Jouni P. Hämäläinen, Rolf Hernberg & Timo Joutsenoja. (1996) Pressurized Pulverized Fuel Combustion in Different Concentrations of Oxygen and Carbon Dioxide. Energy & Fuels 10:1, pages 121-133.
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Kristen P. Brooks & Merrill W. Beckstead. (1995) Dynamics of aluminum combustion. Journal of Propulsion and Power 11:4, pages 769-780.
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Kalyan Annamalai, William Ryan & Senthilvelan Dhanapalan. (1994) Interactive processes in gasification and combustion—Part III: Coal/char particle arrays, streams and clouds. Progress in Energy and Combustion Science 20:6, pages 487-618.
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Jaakko J. Saastamoinen, Martti J. Aho & Veli L. Linna. (1993) Simultaneous pyrolysis and char combustion. Fuel 72:5, pages 599-609.
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Kalyan Annamalai & William Ryan. (1993) Interactive processes in gasification and combustion—II. Isolated carbon, coal and porous char particles. Progress in Energy and Combustion Science 19:5, pages 383-446.
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Sanjay Agrawal & K.C. Midkiff. (1992) Model predictions of the extent of heterogeneous coal combustion during rapid evolution of volatiles. Energy 17:7, pages 669-678.
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Chun Wai Lau & Stephen Niksa. (1992) The combustion of individual particles of various coal types. Combustion and Flame 90:1, pages 45-70.
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J.S. Tsai & Arthur M. Sterling. (1991) The combustion of a linear droplet array in a convective, coaxial potential flow. Combustion and Flame 86:3, pages 189-202.
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M.J. Aho, J.J. Saastamoinen, V.L. Linna & J.T. Rantanen. 1991. 1991 International Conference on Coal Science Proceedings. 1991 International Conference on Coal Science Proceedings 392 395 .
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K. Ohtake & K. Okazaki. (1988) Optical ct measurement and mathematical prediction of multi-temperature in pulverized coal combustion field. International Journal of Heat and Mass Transfer 31:2, pages 397-405.
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L.D. Timothy, D. Froelich, A.F. Sarofim & J.M. B?er. (1988) Soot formation and burnout during the combustion of dispersed pulverized coal particles. Symposium (International) on Combustion 21:1, pages 1141-1148.
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Stephen Niksa, Alan R. Kerstein & Thomas H. Fletcher. (1987) Predicting devolatilization at typical coal combustion conditions with the Distributed-Energy Chain Model. Combustion and Flame 69:2, pages 221-228.
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