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Combustion Science and Technology Volume 48, 1986 - Issue 3-4
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Original Articles

An Investigation of Factors Affecting the Physical Characteristics of Flyash Formed in a Laboratory Scale Combustor

L. J. WIBBERLEY Institute of Coal Research, University of Newcastle, New South Wales, 2308, Australia
&
T. F. WALL Institute of Coal Research, University of Newcastle, New South Wales, 2308, Australia
Pages 177-190 | Received 04 Apr 1985, Accepted 22 Oct 1985, Published online: 29 Mar 2007

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THOMAS GENTZIS, FARIBORZ GOODARZI & ANDREW HICKINBOTHAM. (1995) Mineralogical Composition of the Highvale Mine Coals and Its Impact on Plant Performance. Energy Sources 17:6, pages 681-702.
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S.-G. Kang, A.R. Kerstein, J.J. Helble & A.F. Sarofim. (1990) Simulation of Residual Ash Formation During Pulverized Coal Combustion: Bimodal Ash Particle Size Distribution. Aerosol Science and Technology 13:4, pages 401-412.
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S. SRINIVASACHAR, M. A. TOQAN, J. M. BEÉR & H. M. ETTOUNEY. (1988) Percolation Model for Coal Char Particle Combustion and Fragmentation. Combustion Science and Technology 57:1-3, pages 55-70.
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Felipe Basquiroto de Souza, Oscar Rubem Klegues Montedo, Rosielen Leopoldo Grassi & Elaine Gugliemi Pavei Antunes. (2019) Lightweight high-strength concrete with the use of waste cenosphere as fine aggregate. Matéria (Rio de Janeiro) 24:4.
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Hongwei Wu & Yi Li. (2019) Ash cenosphere fragmentation during pulverised pyrite combustion: Importance of cooling. Proceedings of the Combustion Institute 37:3, pages 2773-2780.
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Sui Boon Liaw, Mohammad Usman Rahim & Hongwei Wu. (2016) Trace Elements Release and Particulate Matter Emission during the Combustion of Char and Volatiles from In Situ Biosolid Fast Pyrolysis . Energy & Fuels 30:7, pages 5766-5771.
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F. Reyes Caballero, S. A. Martínez Ovalle & M. Moreno Gutiérrez. (2015) Mössbauer characterization of feed coal, ash and fly ash from a thermal power plant. Hyperfine Interactions 232:1-3, pages 141-148.
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Yi Li, Xiangpeng Gao & Hongwei Wu. (2013) Ash Cenosphere from Solid Fuels Combustion. Part 2: Significant Role of Ash Cenosphere Fragmentation in Ash and Particulate Matter Formation. Energy & Fuels 27:2, pages 822-829.
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Ginting J. Kusuma, Hideki Shimada, Candra Nugraha, Akihiro Hamanaka, Takashi Sasaoka, Kikuo Matsui, Rudy S. Gautama & Budi Sulistianto. (2013) Study on Co-placement of Coal Combustion Ash-coal Waste Rock for Minimizing Acid Mine Drainage Generation: A Preliminary Result of Field Column Test Experiment. Procedia Earth and Planetary Science 6, pages 251-261.
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Peter Mullinger & Barrie Jenkins. 2013. Industrial and Process Furnaces. Industrial and Process Furnaces 377 413 .
Feyza Kazanc & Yiannis A. Levendis. (2012) Physical Properties of Particulate Matter Emitted from Combustion of Coals of Various Ranks in O 2 /N 2 and O 2 /CO 2 Environments . Energy & Fuels 26:12, pages 7127-7139.
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Ginting J. Kusuma, Hideki Shimada, Takashi Sasaoka, Kikuo Matsui, Candra Nugraha, Rudy S. Gautama & Budi Sulistianto. (2012) An Evaluation on the Physical and Chemical Composition of Coal Combustion Ash and Its Co-Placement with Coal-Mine Waste Rock. Journal of Environmental Protection 03:07, pages 589-596.
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A. Bhattacharjee, H. Mandal, M. Roy, J. Kusz & W. Hofmeister. (2011) Microstructural and magnetic characterization of fly ash from Kolaghat Thermal Power Plant in West Bengal, India. Journal of Magnetism and Magnetic Materials 323:23, pages 3007-3012.
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Minghou Xu, Dunxi Yu, Hong Yao, Xiaowei Liu & Yu Qiao. (2011) Coal combustion-generated aerosols: Formation and properties. Proceedings of the Combustion Institute 33:1, pages 1681-1697.
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Dunxi Yu, Minghou Xu, Hong Yao, Xiaowei Liu, Ke Zhou, Lin Li & Chang Wen. (2009) Mechanisms of the central mode particle formation during pulverized coal combustion. Proceedings of the Combustion Institute 32:2, pages 2075-2082.
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Peter Mullinger & Barrie Jenkins. 2008. Industrial and Process Furnaces. Industrial and Process Furnaces 375 411 .
D. Yu, M.H. Xu, X. Liu, J. Huang & G. Li. (2008) Mechanisms of Submicron and Residual Ash Particle Formation during Pulverised Coal Combustion: A Comprehensive Review. Developments in Chemical Engineering and Mineral Processing 13:3-4, pages 467-482.
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Hongwei Wu, Gary Bryant & Terry Wall. (2000) The Effect of Pressure on Ash Formation during Pulverized Coal Combustion. Energy & Fuels 14:4, pages 745-750.
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Hongwei Wu, Terry Wall, Guisu Liu & Gary Bryant. (1999) Ash Liberation from Included Minerals during Combustion of Pulverized Coal:  The Relationship with Char Structure and Burnout. Energy & Fuels 13:6, pages 1197-1202.
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Philip J. Flanders. (1999) Identifying Fly Ash at a Distance from Fossil Fuel Power Stations. Environmental Science & Technology 33:4, pages 528-532.
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L. L. Baxter, T. R. Miles, T. R. MilesJr.Jr., B. M. Jenkins, T. A. Milne, D. Dayton, R. W. Bryers & L. L. Oden. 1997. Developments in Thermochemical Biomass Conversion. Developments in Thermochemical Biomass Conversion 1424 1444 .
Larry L. Baxter. (1992) Char fragmentation and fly ash formation during pulverized-coal combustion. Combustion and Flame 90:2, pages 174-184.
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Shin G. Kang, Adel F. Sarofim & János M. Beér. (1992) Effect of Char structure on residual ash formation during pulverized coal combustion. Symposium (International) on Combustion 24:1, pages 1153-1159.
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Larry L. Baxter & Reginald E. Mitchell. (1992) The release of iron during the combustion of Illinois No. 6 coal. Combustion and Flame 88:1, pages 1-14.
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Michael L. Jones, David P. Kalmanovitch, Edward N. Steadman, Christopher J. Zygarlicke & Steven A. Benson. 1992. Advances in Coal Spectroscopy. Advances in Coal Spectroscopy 1 27 .
Srivats Srinivasachar, Joseph J. Helble, Arthur A. Boni, Naresh Shah, Gerald P. Huffman & Frank E. Huggins. (1990) Mineral behavior during coal combustion 2. Illite transformations. Progress in Energy and Combustion Science 16:4, pages 293-302.
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J.J. Helble, S. Srinivasachar & A.A. Boni. (1990) Factors influencing the transformation of minerals during pulverized coal combustion. Progress in Energy and Combustion Science 16:4, pages 267-279.
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Larry L. Baxter. (1990) The evolution of mineral particle size distributions during early stages of coal combustion. Progress in Energy and Combustion Science 16:4, pages 261-266.
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J.J. Helble & A.F. Sarofim. (1989) Influence of char fragmentation on ash particle size distributions. Combustion and Flame 76:2, pages 183-196.
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Shin-Gyoo Kang, Joseph J. Helble, Adel F. Sarofim & János M. Beér. (1989) Time-resolved evolution of fly ash during pulverized coal combustion. Symposium (International) on Combustion 22:1, pages 231-238.
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D. Dunn-Rankin & A.R. Kerstein. (1988) Influence of ash on particle size distribution evolution during coal combustion. Combustion and Flame 74:2, pages 207-218.
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J. Helble, M. Neville & A.F. Sarofim. (1988) Aggregate formation from vaporized ash during pulverized coal combustion. Symposium (International) on Combustion 21:1, pages 411-417.
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Derek Dunn-Rankin & Alan R. Kerstein. (1987) Numerical simulation of particle size distribution evolution during pulverized coal combustion. Combustion and Flame 69:2, pages 193-209.
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