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Combustion Science and Technology Volume 26, 1981 - Issue 3-4
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Original Articles

Fly Ash Characteristics and Radiative Heat Transfer in Pulverized-Coal-Fired Furnaces

T. F. WALL Department of Chemical Engineering, The University of Newcastle, N.S.W, 2308, Australia
,
A. LOWE Department of Chemical Engineering, The University of Newcastle, N.S.W, 2308, Australia
,
L J. WIBBERLEY Department of Chemical Engineering, The University of Newcastle, N.S.W, 2308, Australia
,
T. MAI-VIET Department of Chemical Engineering, The University of Newcastle, N.S.W, 2308, Australia
&
R. P. GUPTA Department of Chemical Engineering, The University of Newcastle, N.S.W, 2308, Australia
Pages 107-121 | Received 15 Dec 1980, Accepted 12 Mar 1981, Published online: 27 Apr 2007

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Shesh N. Dhurandhar, Ankit Bansal, Sivaram Pramod Boppudi & Medha Dakshina Murty Kadiyala. (2022) Application and comparative analysis of radiative heat transfer models for coal-fired furnace. Numerical Heat Transfer, Part A: Applications 82:4, pages 137-168.
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M. P. MENGÜC & R. VISKANTA. (1987) A Sensitivity Analysis for Radiative Heat Transfer in a Pulverized Coal-Fired Furnace. Combustion Science and Technology 51:1-3, pages 51-74.
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Articles from other publishers (29)

Nimeti Doner, Huseyin Topal, Agah Aygahoglu, Fatih Sen & Hassan Karimi-Maleh. (2022) Study on particle radiative properties of lignite, hard coal and biomass fly ashes in the infrared wavelength range. Chemosphere 291, pages 132719.
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Michael F. Modest & Sandip Mazumder. 2022. Radiative Heat Transfer. Radiative Heat Transfer 401 452 .
G. Sankar, D. Santhosh Kumar & K.R. Balasubramanian. (2019) Computational modeling of pulverized coal fired boilers – A review on the current position. Fuel 236, pages 643-665.
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Cihan Ates, Nevin Selçuk & Gorkem Kulah. (2018) Influence of gray particle assumption on the predictive accuracy of gas property approximations. Journal of Quantitative Spectroscopy and Radiative Transfer 220, pages 67-83.
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Cihan Ates, Nevin Selçuk & Gorkem Kulah. (2018) Influence of fly ash composition on non-gray particle radiation in combusting systems. Journal of Quantitative Spectroscopy and Radiative Transfer 215, pages 25-40.
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Robert Johansson, Tim Gronarz & Reinhold Kneer. (2017) Influence of Index of Refraction and Particle Size Distribution on Radiative Heat Transfer in a Pulverized Coal Combustion Furnace. Journal of Heat Transfer 139:4.
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Tim Gronarz, Jan Schulze, Mischka Laemmerhold, Philipp Graeser, Jeanette Gorewoda, Vitali Kez, Martin Habermehl, Martin Schiemann, Jochen Ströhle, Bernd Epple, Viktor Scherer & Reinhold Kneer. (2017) Quantification of the influence of parameters determining radiative heat transfer in an oxy-fuel operated boiler. Fuel Processing Technology 157, pages 76-89.
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Alastair G. Clements, Sandy Black, János Szuhánszki, Katarzyna Stęchły, Alessandro Pranzitelli, William Nimmo & Mohamed Pourkashanian. (2015) LES and RANS of air and oxy-coal combustion in a pilot-scale facility: Predictions of radiative heat transfer. Fuel 151, pages 146-155.
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Michael F Modest. 2013. Radiative Heat Transfer. Radiative Heat Transfer 387 439 .
Michael F. Modest. 2003. Radiative Heat Transfer. Radiative Heat Transfer 361 412 .
Huai-Chun Zhou, Yu-Bo Hou, Dong-Lin Chen & Chu-Guang Zheng. (2002) An inverse radiative transfer problem of simultaneously estimating profiles of temperature and radiative parameters from boundary intensity and temperature measurements. Journal of Quantitative Spectroscopy and Radiative Transfer 74:5, pages 605-620.
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Huai-Chun Zhou, Shu-Dong Han, Feng Sheng & Chu-Guang Zheng. (2002) Visualization of three-dimensional temperature distributions in a large-scale furnace via regularized reconstruction from radiative energy images: numerical studies. Journal of Quantitative Spectroscopy and Radiative Transfer 72:4, pages 361-383.
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A A Samarian, O S Vaulina, A P Nefedov, O F Petrov & A I Denisenko. (2002) Optical Diagnostics of Plasma and Particle in an Atmospheric Pressure Dusty Plasma. Physica Scripta 66:1, pages 82-88.
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Olga S. Vaulina, Anatoli P. Nefedov, Oleg F. Petrov, Alex A. Samarian & Alexander W. Chernyschev. (1998) Temperature measurements of optically non-gray particles in high-temperature dusty media. Combustion and Flame 115:3, pages 364-371.
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Anatoli P. Nefedov, Oleg F. Petrov & Olga S. Vaulina. (1997) Analysis of particle sizes, concentration, and refractive index in measurement of light transmittance in the forward-scattering-angle range. Applied Optics 36:6, pages 1357.
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M. Filla, A. Scalabrin & C. Tonfoni. (1996) Scattering of thermal radiation in the freeboard of a 1 MWt fluidized bed combustion with coal and limestone feeding. Symposium (International) on Combustion 26:2, pages 3295-3300.
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Changsik Kim & Noam Lior. (1995) Easily computable good approximations for spectral radiative properties of particle—gas components and mixture in pulverized coal combustors. Fuel 74:12, pages 1891-1902.
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Sarbajit Ghosal, Jon L. Ebert & Sidney A. Self. (1995) Chemical composition and size distributions for fly ashes. Fuel Processing Technology 44:1-3, pages 81-94.
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Fengshan Liu & Jim Swithenbank. (1993) The effects of particle size distribution and refractive index on fly-ash radiative properties using a simplified approach. International Journal of Heat and Mass Transfer 36:7, pages 1905-1912.
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A. Lohi, J. R. Wynnyckyj & E. Rhodes. (2009) Spectral measurement of the complex refractive index of fly ashes of canadian lignite and sub‐bituminous coals. The Canadian Journal of Chemical Engineering 70:4, pages 751-758.
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D.G. Goodwin & M. Mitchner. (1989) Flyash radiative properties and effects on radiative heat transfer in coal-fired systems. International Journal of Heat and Mass Transfer 32:4, pages 627-638.
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D. G. Goodwin & M. Mitchner. (1989) Infrared optical constants of coal slags - Dependence on chemical composition. Journal of Thermophysics and Heat Transfer 3:1, pages 53-60.
Crossref
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.
Crossref
Adel F. Sarofim. (1988) Radiative heat transfer in combustion: Friend or foe. Symposium (International) on Combustion 21:1, pages 1-23.
Crossref
S.A Boothroyd, A.R Jones, K.W Nicholson & R Wood. (1987) Light scattering by fly ash and the applicability of Mie theory. Combustion and Flame 69:2, pages 235-241.
Crossref
R.P. Gupta & T.F. Wall. (1985) The optical properties of fly ash in coal fired furnaces. Combustion and Flame 61:2, pages 145-151.
Crossref
R.P. Gupta, T.F. Wall & J.S. Truelove. (1983) Radiative scatter by fly ash in pulverized-coal-fired furnaces: Application of the Monte Carlo method to anisotropic scatter. International Journal of Heat and Mass Transfer 26:11, pages 1649-1660.
Crossref
L.Douglas Smoot & Scott C. Hill. (1983) Critical requirements in combustion research. Progress in Energy and Combustion Science 9:1-2, pages 77-103.
Crossref
T.F. Wall, H.T. Duong, I.McC. Stewart & J.S. Truelove. (1982) Radiative heat transfer in furnaces: Flame and furnace models of the IFRF M1- and M2-trials. Symposium (International) on Combustion 19:1, pages 537-547.
Crossref

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